Modified orthopoxvirus vectors

ABSTRACT

The disclosure relates to modified orthopoxvirus vectors, as well as methods of using the same for the treatment of various cancers. The disclosure provides modified orthopoxvirus vectors that exhibit various beneficial therapeutic activities, including enhanced oncolytic activity, spread of infection, immune evasion, tumor persistence, capacity for incorporation of exogenous DNA sequences and safety. The viruses we have discovered are also amenable to large scale manufacturing protocols.

FIELD

The invention relates to the field of immunotherapy, e.g., for the treatment of cell proliferation disorders, such as cancers. Particularly, the invention relates to genetically modified orthopoxviruses, as well as methods of making and using the same.

BACKGROUND

The immune system may be stimulated to identify tumor cells and target them for destruction. Immunotherapy employing oncolytic orthopoxviruses is a rapidly evolving area in cancer research. New approaches are needed to engineer and/or enhance tumor-selectivity for oncolytic viruses in order to maximize efficiency and safety. This selectivity is especially important when potentially toxic therapeutic agents or genes are added to the viruses.

Although the use of orthopoxviruses as clinical oncolytic vectors is a promising paradigm for cancer treatment, due to toxicity, such as pox lesions in patients, and immunosuppressive side effects, most current clinical candidates have shown only modest clinical success. There exists a need for methods to engineer orthopoxviruses that exhibit more robust virus replication, cancer cell killing, and spreading from the point of infection. The present invention addresses this need and provides a solution to selectivity and safety limitations by employing a modified vaccinia virus.

SUMMARY

The present disclosure describes the use of orthopoxviruses for the treatment of cancer. In particular, the disclosure is based in part on the surprisingly enhanced oncolytic activity, spread of infection, and safety results engendered when a orthopoxvirus is genetically modified to contain deletions in one or more, or all, of the following genes: C2L, C1L, N1 L, N2L, M1 L, M2L, K1 L, K2L, K3L, K4L, K5L, K6L, K7R, F1 L, F2L, F3L, B14R, B15R, B16R, B17L, B18R, B19R, B20R, K ORF A, K ORF B, B ORF E, B ORF F, B ORF G, B21R, B22R, B23R, B24R, B25R, B26R, B27R, B28R, and B29R. Genetically modified orthopoxviruses, such as vaccinia viruses (e.g., Copenhagen, Western Reserve, Wyeth, Lister, EM63, ACAM2000, CV-1, modified vaccinia Ankara (MVA), Dairen I, GLV-1h68, IHD-J, L-IVP, LC16m8, LC16mO, Tashkent, Tian Tan, and WAU86/88-1 viruses) that exhibit mutations in one or more, or all, of these genes may exhibit an array of beneficial features, such as improved oncolytic ability, replication in tumors, infectivity, immune evasion, tumor persistence, capacity for incorporation of exogenous DNA sequences, and/or amenability for large scale manufacturing. The present disclosure describes orthopox viruses further genetically modified to contain deletions in the B8R gene. In various embodiments disclosed below, the invention may or may not include a deletion of the B8R gene. In various embodiments, the modified orthopoxvirus expresses at least one of three transgenes: IL-12-TM, FLT3-L and anti-CTLA4 antibody.

In a first aspect, the invention features a nucleic acid that includes a recombinant orthopoxvirus genome, wherein the recombinant orthopoxvirus genome has a deletion of at least 2, 3, 4, 5, 6, 7, 8, 9, 10, 11, 12, 13, 14, 15, 16, 17, 18, 19, 20, 21 or 22 genes, each independently selected from the group consisting of C2L, C1L, N1L, N2L, ML, M2L, K1L, K2L, K3L, K4L, K5L, K6L, K7R, F1L, F2L, F3L, B14R, B15R, B16R, B17L, B18R, B19R, 820R. In some embodiments, the deletion includes each of C2L, C1L, N1L, N2L, M1L, M2L, K1L, K2L, K3L, K4L, K5L, K6L, K7R, F1L, F2L, F3L, B14R, B15R, B16R, B17L, B18R, B19R, B20R genes. In any one of the embodiments, disclosed herein, the recombinant orthopoxvirus genome may further include a deletion of the B8R gene.

In another aspect, the invention features a nucleic acid that includes a recombinant orthopoxvirus genome, wherein the recombinant orthopoxvirus genome has a deletion of at least 1 gene selected from the group consisting of B14R, B16R, B17L, B18R, B19R, and B20R. In some embodiments, the deletion includes at least 2, 3, 4, or 5 genes, each independently selected from the group consisting of B14R, B16R, B17L, B18R, B19R, and B20R. In some embodiments, the deletion includes each of B14R, B16R, B17L, B18R, B19R, and B20R. In any one of the embodiments, disclosed herein, the recombinant orthopoxvirus genome may further include a 88R deletion.

In another aspect, the invention features a nucleic acid that includes a recombinant orthopoxvirus genome, wherein the recombinant orthopoxvirus genome has a deletion of at least 1 gene selected from the group consisting of C2L, C1L, N1L, N2L, M1L, M2L, K1L, K2L, K3L, K4L, K5L, K6L, K7R, F1L, F2L, and F3L. In some embodiments, the deletion includes at least 2, 3, 4, 5, 6, 7, 8, 9, 10, 11, 12, 13, 14, or 15 genes, each independently selected from the group consisting of C2L, C1L, N1L, N2L, M1L, M2L, K1L, K2L, K3L, K4L, K5L, K6L, K7R, F1 L, F2L, and F3L. In some embodiments, the deletion includes each of C2L, C1L, N1L, N2L, M1L, M2L, K1L, K2L, K3L, K4L, K5L, K6L, K7R, F1L, F2L, and F3L. In any one of the embodiments, disclosed herein, the recombinant orthopoxvirus genome may further include a B8R deletion.

In another aspect, the invention features a nucleic acid that includes a recombinant orthopoxvirus genome, wherein the recombinant orthopoxvirus genome has a deletion of at least 1 gene that encodes a caspase-9 inhibitor.

In some embodiments, the recombinant orthopoxvirus genome has a deletion of at least 1 gene that encodes a caspase-9 inhibitor. In some embodiments, the gene that encodes a caspase-9 inhibitor is F1L.

In another aspect, the invention features a nucleic acid that includes a recombinant orthopoxvirus genome, wherein the recombinant orthopoxvirus genome has a deletion of at least 1 gene that encodes a BCL-2 inhibitor.

In some embodiments, the recombinant orthopoxvirus genome has a deletion of at least 1 gene that encodes a BCL-2 inhibitor. In some embodiments, the gene that encodes a BCL-2 inhibitor is N L.

In another aspect, the invention features a nucleic acid that includes a recombinant orthopoxvirus genome, wherein the recombinant orthopoxvirus genome has a deletion of at least 1 gene that encodes a dUTPase.

In some embodiments, the recombinant orthopoxvirus genome has a deletion of at least 1 gene that encodes a dUTPase. In some embodiments, the gene that encodes a dUTPase is F2L.

In another aspect, the invention features a nucleic acid that includes a recombinant orthopoxvirus genome, wherein the recombinant orthopoxvirus genome has a deletion of at least 1 gene that encodes a IFN-alpha/beta-receptor-like secreted glycoprotein.

In some embodiments, the recombinant orthopoxvirus genome has a deletion of at least 1 gene that encodes a IFN-alpha/beta-receptor-like secreted glycoprotein. In some embodiments, the gene that encodes a IFN-alpha/beta-receptor-like secreted glycoprotein is B19R.

In another aspect, the invention features a nucleic acid that includes a recombinant orthopoxvirus genome, wherein the recombinant orthopoxvirus genome has a deletion of at least 1 gene that encodes an IL-1-beta-inhibitor.

In some embodiments, the recombinant orthopoxvirus genome has a deletion of at least 1 gene that encodes an IL-1-beta-inhibitor. In some embodiments, the gene that encodes an IL-1-beta-inhibitor is B16R.

In another aspect, the invention features a nucleic acid that includes a recombinant orthopoxvirus genome, wherein the recombinant orthopoxvirus genome has a deletion of at least 1 gene that encodes a phospholipase-D.

In some embodiments, the recombinant orthopoxvirus genome has a deletion of at least 1 gene that encodes a phospholipase-D. In some embodiments, the gene that encodes a phospholipase-D is K4L.

In another aspect, the invention features a nucleic acid that includes a recombinant orthopoxvirus genome, wherein the recombinant orthopoxvirus genome has a deletion of at least 1 gene that encodes a PKR inhibitor.

In some embodiments, the recombinant orthopoxvirus genome has a deletion of at least 1 gene that encodes a PKR inhibitor. In some embodiments, the gene that encodes a PKR inhibitor is K3L.

In another aspect, the invention features a nucleic acid that includes a recombinant orthopoxvirus genome, wherein the recombinant orthopoxvirus genome has a deletion of at least 1 gene that encodes a serine protease inhibitor.

In some embodiments, the recombinant orthopoxvirus genome has a deletion of at least 1 gene that encodes a serine protease inhibitor. In some embodiments, the gene that encodes a serine protease inhibitor is K2L.

In another aspect, the invention features a nucleic acid that includes a recombinant orthopoxvirus genome, wherein the recombinant orthopoxvirus genome has a deletion of at least 1 gene that encodes a TLR signaling inhibitor. In some embodiments, the recombinant orthopoxvirus genome has a deletion of at least 1 gene that encodes a TLR signaling inhibitor. In some embodiments, the gene that encodes a TLR signaling inhibitor is N2L.

In another aspect, the invention features a nucleic acid that includes a recombinant orthopoxvirus genome, wherein the recombinant orthopoxvirus genome has a deletion of at least 1 gene that encodes a kelch-like protein. In some embodiments, the recombinant orthopoxvirus genome has a deletion of at least 1 gene that encodes a kelch-like protein. In some embodiments, the recombinant orthopoxvirus genome has a deletion of at least 2 genes that each encodes a kelch-like protein. In some embodiments, the genes that encode a kelch-like protein are, independently, selected from the group consisting of F3L and C2L.

In another aspect, the invention features a nucleic acid that includes a recombinant orthopoxvirus genome, wherein the recombinant orthopoxvirus genome has a deletion of at least 1 gene that encodes a monoglyceride lipase.

In some embodiments, the recombinant orthopoxvirus genome has a deletion of at least 1 or 2 genes that encodes a monoglyceride lipase. In some embodiments, the genes that encode a monoglyceride lipase are, independently, selected from the group consisting of K5L and K6L.

In another aspect, the invention features a nucleic acid that includes a recombinant orthopoxvirus genome, wherein the recombinant orthopoxvirus genome has a deletion of at least 1, 2 or 3 genes that encodes an NF-κB inhibitor. In some embodiments, the genes that encode an NF-κB inhibitor are, independently selected from the group consisting of K7R, K1L, and M2L.

In another aspect, the invention features a nucleic acid that includes a recombinant orthopoxvirus genome, wherein the recombinant orthopoxvirus genome has a deletion of at least 1, 2, or 3 genes that encodes an Ankyrin repeat protein. In some embodiments, the genes that encode an Ankyrin repeat protein are, independently, selected from the group consisting of B18R, B20R, and M1L.

In another aspect, the invention features a nucleic acid that includes a recombinant orthopoxvirus genome, wherein the recombinant orthopoxvirus genome has a deletion of at least 1, 2 or 3 genes each independently selected from the group consisting of B15R, B17L, and B14R. In another aspect, the invention features a nucleic acid that includes a recombinant orthopoxvirus genome, wherein the recombinant orthopoxvirus genome has a deletion of at least 1, 2, 3, or 4, gene selected from the group consisting of K ORF A, K ORF B, B ORF E, B ORF F, and B ORF G. In any one of the embodiments, disclosed herein, the recombinant orthopoxvirus genome further includes a B8R deletion.

In some embodiments, the recombinant orthopoxvirus genome has a deletion of at least 1 gene selected from the group of inverted terminal repeat (ITR) genes consisting of B21R, B22R, B23R, B24R, B25R, B26R, B27R, B28R, and B29R. In some embodiments, the deletion includes at least 2, 3, 4, 5, 6, 7, or 8 genes, each independently selected from the group of ITR genes consisting of B21R, B22R, B23R, B24R, B25R, B26R, B27R, B28R, and B29R. In some embodiments, the deletion includes each of B21R, B22R, B23R, B24R, B25R, B26R, B27R, B28R, and B29R. In any one of the embodiments, disclosed herein, the recombinant orthopoxvirus genome may further include a B8R deletion.

In some embodiments, the vaccinia virus is a strain selected from the group consisting of Copenhagen, Western Reserve, Wyeth, Lister, EM63, ACAM2000, CV-1, modified vaccinia Ankara (MVA), Dairen I, GLV-1h68, IHD-J, L-IVP, LC16m8, LC16mO, Tashkent, Tian Tan, and WAU86/88-1 In some embodiments, the vaccinia virus is a strain selected from the group consisting of Copenhagen, Western Reserve, Tian Tan, Wyeth, and Lister. In some embodiments, the vaccinia virus is a Copenhagen strain vaccinia virus.

In some embodiments, one or more, or all, of the deletions is a deletion of the entire polynucleotide encoding the corresponding gene. In some embodiments, one or more, or all, of the deletions is a deletion of a portion of the polynucleotide encoding the corresponding gene, such that the deletion is sufficient to render the gene nonfunctional, e.g., upon introduction into a host cell.

In some embodiments, the nucleic acid further includes a transgene encoding a tumor-associated antigen. In some embodiments, the tumor-associated antigen is a tumor-associated antigen listed in any one of Tables 3-30 herein. In some embodiments, the tumor-associated antigen is a tumor-associated antigen selected from the group consisting of CD19, CD33, EpCAM, CEA, PSMA, EGFRvIII, CD133, EGFR, CDH19, ENPP3, DLL3, MSLN, ROR1, HER2, HLAA2, EpHA2, EpHA3, MCSP, CSPG4, NG2, RON, FLT3, BCMA, CD20, FAPα, FRα, CA-9, PDGFRα, PDGFRβ, FSP1, S100A4, ADAM12m, RET, MET, FGFR, INSR, and NTRK. In some embodiments, the tumor-associated antigen includes MAGE-A3, or one or more fragments thereof. In some embodiments, the tumor-associated antigen includes NY-ESO-1, or one or more fragments thereof. In some embodiments, the tumor-associated antigen includes one or mom human papillomavirus (HPV) proteins, or fragments thereof. In some embodiments, the tumor-associated antigen includes (i) E6 and E7 proteins, or fragments thereof, of HPV16 and (ii) E6 and E7 proteins, or fragments thereof, of HPV18. In some embodiments, the tumor-associated antigen includes brachyury or one or more fragments thereof. In some embodiments, the tumor-associated antigen includes prostatic acid phosphatase, or one or more fragments thereof.

In some embodiments, the nucleic acid further includes a transgene encoding an immune checkpoint inhibitor. In some embodiments, the immune checkpoint inhibitor is selected from the group consisting of OX40 ligand, ICOS ligand, anti-CD47 antibody or antigen-binding fragment thereof, anti-CD40/CD40L antibody or antigen-binding fragment thereof, anti-Lag3 antibody or antigen-binding fragment thereof, anti-CTLA-4 antibody or antigen-binding fragment thereof, anti-PD-L1 antibody or antigen-binding fragment thereof, anti-PD1 antibody or antigen-binding fragment thereof, and anti-Tim-3 antibody or antigen-binding fragment thereof. In some embodiments, the immune checkpoint inhibitor is an anti-PD1 antibody or antigen-binding fragment thereof or an anti-CTLA-4 antibody or antigen-binding fragment thereof. In some embodiments, the immune checkpoint inhibitor is an anti-PD1 antibody or antigen-binding fragment thereof. In some embodiments, the immune checkpoint inhibitor is an anti-CTLA-4 antibody or antigen-binding fragment thereof.

Antibodies or antigen-binding fragments thereof described herein may be full-length antibodies or antibody fragments, such as a monoclonal antibody or antigen-binding fragment thereof, a polyclonal antibody or antigen-binding fragment thereof, a humanized antibody or antigen-binding fragment thereof, a primatized antibody or antigen-binding fragment thereof, a bispecific antibody or antigen-binding fragment thereof, a multi-specific antibody or antigen-binding fragment thereof, a dual-variable immunoglobulin domain, a monovalent antibody or antigen-binding fragment thereof, a chimeric antibody or antigen-binding fragment thereof, a single-chain Fv molecule (scFv), a diabody, a triabody, a nanobody, an antibody-like protein scaffold, a domain antibody, a Fv fragment, a Fab fragment, a F(ab′)₂ molecule, and a tandem scFv (taFv). In some embodiments, the antibody or antigen-binding fragment thereof contains two or more CDRs covalently bound to one another, e.g., by an amide bond, a thioether bond, a carbon-carbon bond, or a disulfide bridge, or by a linker, such as a linker described herein. In some embodiments, the antibody or antigen-binding fragment thereof is a single-chain polypeptide. In some embodiments, the antibody or antigen-binding fragment thereof has an isotype selected from the group consisting of IgG, IgA, IgM, IgD, and IgE.

In some embodiments, the nucleic acid further includes a transgene encoding an interleukin. In some embodiments, the interleukin (IL) is selected from the group consisting of IL-1 alpha, IL-1 beta, IL-2, IL-4, IL-7, IL-10, IL-12 p35, IL-12 p40, IL-12 p70, IL-15, IL-18, IL-21, and IL-23. In some embodiments, the interleukin is selected from the group consisting of IL-12 p35, IL-12 p40, and IL-12 p70. In some embodiments, the interleukin is membrane-bound.

In some embodiments, the nucleic acid further includes a transgene encoding an interferon. In some embodiments, the interferon is selected from the group consisting of IFN-alpha, IFN-beta, IFN-delta, IFN-epsilon, IFN-tau, IFN-omega, IFN-zeta, and IFN-gamma.

In some embodiments, the nucleic acid further includes a transgene encoding a TNF superfamily member protein. In some embodiments, the TNF superfamily member protein is selected from the group consisting of TRAIL, Fas ligand, LIGHT (TNFSF-14), TNF-alpha, and 4-1BB ligand.

In some embodiments, the nucleic acid further includes a transgene encoding a cytokine. In some embodiments, the cytokine selected from the group consisting of GM-CSF, FMS-like tyrosine kinase 3 ligand (Flt3 ligand), CD40 ligand, anti-TGF-beta, anti-VEGF-R2, and guanyl adenylate cyclase (cGAS). In some embodiments, the cytokine is Flt3 ligand.

In another aspect, the invention features a recombinant orthopoxvirus vector that has a deletion of at least 2, 3, 4, 5, 6, 7, 8, 9, 10, 11, 12, 13, 14, 15, 16, 17, 18, 19, 20, 21 or 22 genes, each independently selected from the group consisting of C2L, C1L, N1L, N2L, M1L, M2L, K1L, K2L, K3L, K4L, K5L, K6L, K7R, F1L, F2L, F3L, B14R, B15R, B16R, B17L, B18R, B19R, B20R. In some embodiments, the deletion includes each of C2L, C1L, N1L, N2L, M1L, M2L, K1L, K2L, K3L, K4L, K5L, K6L, K7R, F1L, F2L, F3L, B14R, B15R, B16R, B17L, B18R, B19R, and B20R. In anyone of the embodiments, disclosed herein, the recombinant orthopoxvirus genome may further include a B8R deletion.

In another aspect, the invention features a recombinant orthopoxvirus vector that includes a recombinant orthopoxvirus genome, wherein the recombinant orthopoxvirus genome has a deletion of at least 1 gene selected from the group consisting of B14R, B16R, B17L, B18R, B19R, and B20R. In some embodiments, the deletion includes at least 2, 3, 4, or 5 genes, each independently selected from the group consisting of B14R, B16R, B17L, B18R, B19R, and B20R. In some embodiments, the deletion includes each of B14R, B16R, B17L, B18R, B19R, and B20R. In anyone of the embodiments, disclosed herein, the recombinant orthopoxvirus genome may further include a B8R deletion.

In another aspect, the invention features a recombinant orthopoxvirus vector that includes a recombinant orthopoxvirus genome, wherein the recombinant orthopoxvirus genome has a deletion of at least 1 gene selected from the group consisting of C2L, C1L, N1L, N2L, M1L, M2L, K1L, K2L, K3L, K4L, K5L, K6L, K7R, F1L, F2L, and F3L. In anyone of the embodiments, disclosed herein, the recombinant orthopoxvirus genome may further include a B8R deletion.

In some embodiments, the recombinant orthopoxvirus vector has a deletion of at least 1 gene selected from the group consisting of C2L, C1L, N1L, N2L, M1L, K1L, K2L, K3L, K4L, K7R, and F2L. In some embodiments, the deletion includes at least 2, 3, 4, 5, 6, 7, 8, 9, 10, 11, 12, 13, 14, 15, or 16 genes, each independently selected from the group consisting of C2L, C1L, N1L, N2L, M1L, M2L, K1L, K2L, K3L, K4L, K5L, K6L, K7R, F1L, F2L, and F3L. In some embodiments, the deletion includes each of C2L, C1L, N1L, N2L, M1L, M2L, K1L, K2L, K3L, K4L, K5L, K6L, K7R, F1L, F2L, and F3L. In any one of the embodiments, disclosed herein, the recombinant orthopoxvirus genome may further include a B8R deletion.

In another aspect, the invention features a recombinant orthopoxvirus vector that has a deletion of at least 1 gene that encodes a caspase-9 inhibitor.

In some embodiments, the recombinant orthopoxvirus genome has a deletion of at least 1 gene that encodes a caspase-9 inhibitor. In some embodiments, the gene that encodes a caspase-9 inhibitor is F1L.

In another aspect, the invention features a recombinant orthopoxvirus vector has a deletion of at least 1 gene that encodes a BCL-2 inhibitor.

In some embodiments, the recombinant orthopoxvirus genome has a deletion of at least 1 gene that encodes a BCL-2 inhibitor. In some embodiments, the gene that encodes a BCL-2 inhibitor is N1L.

In another aspect, the invention features a recombinant orthopoxvirus vector has a deletion of at least 1 gene that encodes a dUTPase.

In some embodiments, the recombinant orthopoxvirus genome has a deletion of at least 1 gene that encodes a dUTPase. In some embodiments, the gene that encodes a dUTPase is F2L.

In another aspect, the invention features a recombinant orthopoxvirus vector has a deletion of at least 1 gene that encodes a IFN-alpha/beta-receptor-like secreted glycoprotein.

In some embodiments, the recombinant orthopoxvirus genome has a deletion of at least 1 gene that encodes a IFN-alpha/beta-receptor-like secreted glycoprotein. In some embodiments, the gene that encodes a IFN-alpha/beta-receptor-like secreted glycoprotein is B19R.

In another aspect, the invention features a recombinant orthopoxvirus vector has a deletion of at least 1 gene that encodes an IL-1-beta-inhibitor.

In some embodiments, the recombinant orthopoxvirus genome has a deletion of at least 1 gene that encodes an IL-1-beta-inhibitor. In some embodiments, the gene that encodes an IL-1-beta-inhibitor is B16R.

In another aspect, the invention features a recombinant orthopoxvirus vector has a deletion of at least 1 gene that encodes a phospholipase-D.

In some embodiments, the recombinant orthopoxvirus genome has a deletion of at least 1 gene that encodes a phospholipase-D. In some embodiments, the gene that encodes a phospholipase-D is K4L.

In another aspect, the invention features a recombinant orthopoxvirus vector has a deletion of at least 1 gene that encodes a PKR inhibitor.

In some embodiments, the recombinant orthopoxvirus genome has a deletion of at least 1 gene that encodes a PKR inhibitor. In some embodiments, the gene that encodes a PKR inhibitor is K3L.

In another aspect, the invention features a recombinant orthopoxvirus vector has a deletion of at least 1 gene that encodes a serine protease inhibitor.

In some embodiments, the recombinant orthopoxvirus genome has a deletion of at least 1 gene that encodes a serine protease inhibitor. In some embodiments, the gene that encodes a serine protease inhibitor is K2L.

In another aspect, the invention features a recombinant orthopoxvirus vector has a deletion of at least 1 gene that encodes a TLR signaling inhibitor.

In some embodiments, the recombinant orthopoxvirus genome has a deletion of at least 1 gene that encodes a TLR signaling inhibitor. In some embodiments, the gene that encodes a TLR signaling inhibitor is N2L.

In another aspect, the invention features a recombinant orthopoxvirus vector has a deletion of at least 1 gene that encodes a kelch-like protein.

In some embodiments, the recombinant orthopoxvirus genome has a deletion of at least 1 or 2 genes that encodes a kelch-like protein. In some embodiments, the genes that encode a kelch-like protein are, independently, selected from the group consisting of F3L and C2L.

In another aspect, the invention features a recombinant orthopoxvirus vector has a deletion of at least 1 gene that encodes a monoglyceride lipase.

In some embodiments, the recombinant orthopoxvirus genome has a deletion of at least 1 gene that encodes a monoglyceride lipase. In some embodiments, the recombinant orthopoxvirus genome has a deletion of at least 2 genes that each encodes a monoglyceride lipase. In some embodiments, the genes that encode a monoglyceride lipase are, independently, selected from the group consisting of K5L and K6L.

In another aspect, the invention features a recombinant orthopoxvirus vector has a deletion of at least 1 gene that encodes an NF-κB inhibitor.

In some embodiments, the recombinant orthopoxvirus genome has a deletion of at least 1, 2, or 3 genes that encodes an NF-κB inhibitor. In some embodiments, the genes that encode an NF-κB inhibitor are, independently, selected from the group consisting of K7R, K1L, and M2L.

In another aspect, the invention features a recombinant orthopoxvirus vector has a deletion of at least 1 gene that encodes an Ankyrin repeat protein.

In some embodiments, the recombinant orthopoxvirus genome has a deletion of at least 1 gene that encodes an Ankyrin repeat protein. In some embodiments, the recombinant orthopoxvirus genome has a deletion of at least 2 genes that each encodes an Ankyrin repeat protein. In some embodiments, the recombinant orthopoxvirus genome has a deletion of at least 3 genes that each encodes an Ankyrin repeat protein. In some embodiments, the genes that encode an Ankyrin repeat protein are, independently, selected from the group consisting of B18R, B20R, and M1L.

In another aspect, the invention features a recombinant orthopoxvirus vector has a deletion of at least 1 gene selected from the group consisting of B15R, B17L, and B14R.

In some embodiments, the recombinant orthopoxvirus genome has a deletion of at least 1 gene selected from the group consisting of B15R, B17L, and B14R. In some embodiments, the recombinant orthopoxvirus genome has a deletion of at least 2 genes selected from the group consisting of B15R, B17L, and B14R. In some embodiments, the recombinant orthopoxvirus genome has a deletion of at least 3 genes selected from the group consisting of B15R, B17L, and B14R. In any one of the embodiments, disclosed herein, the recombinant orthopoxvirus genome may further include a B8R deletion.

In another aspect, the invention features a recombinant orthopoxvirus vector that includes a recombinant orthopoxvirus genome, wherein the recombinant orthopoxvirus genome has a deletion of at least 1 gene selected from the group consisting of K ORF A, K ORF B, B ORF E, B ORF F, and B ORF G.

In some embodiments, the recombinant orthopoxvirus vector has a deletion of at least 1 gene selected from the group consisting of K ORF A, K ORF B, B ORF E, B ORF F, and B ORF G. In some embodiments, the vector has a deletion of at least 2, 3, or 4 genes selected from the group consisting of K ORF A, K ORF B, B ORF E, B ORF F, and B ORF G. In some embodiments, the deletion includes each of K ORF A, K ORF B, B ORF E, B ORF F, and B ORF G. In any one of the embodiments, disclosed herein, the recombinant orthopoxvirus genome may further include a B8R deletion.

In some embodiments, the recombinant orthopoxvirus vector has a deletion of at least 1 gene selected from the group of ITR genes consisting of B21R, B22R, B23R, B24R, B25R, B26R, B27R, B28R, and B29R. In some embodiments, the deletion includes at least 2, 3, 4, 5, 6, 7 or 8 genes, each independently selected from the group of ITR genes consisting of B21R, B22R, B23R, B24R, B25R, B26R, B27R, 1B28R, and B29R. In some embodiments, the deletion includes each of B21R, B22R, B23R, B24R, B25R, B26R, B27R, B28R, and B29L In anyone of the embodiments, disclosed herein, the recombinant orthopoxvirus genome may further include a B8R deletion.

In some embodiments, the orthopoxvirus is a vaccinia virus.

In some embodiments, the vaccinia virus is a strain selected from the group consisting of Copenhagen, Western Reserve, Wyeth, Lister, EM63, ACAM2000, CV-1, modified vaccinia Ankara (MVA), Dairen I, GLV-1h68, IHD-J, L-IVP, LC16m8, LC16mO, Tashkent, Tian Tan, and WAU86/88-1. In some embodiments, the vaccinia virus is a strain selected from the group consisting of Copenhagen, Western Reserve, Tian Tan, Wyeth, and Lister. In some embodiments, the vaccinia virus is a Copenhagen strain vaccinia virus.

In some embodiments, one or more, or all, of the deletions is a deletion of the entire polynucleotide encoding the corresponding gene. In some embodiments, one or more, or all, of the deletions is a deletion of a portion of the polynucleotide encoding the corresponding gene, such that the deletion is sufficient to render the gene nonfunctional, e.g., upon introduction into a host cell.

In some embodiments, the vector further includes a transgene encoding a tumor-associated antigen. In some embodiments, the tumor-associated antigen is a tumor-associated antigen listed in any one of Tables 3-30 herein. In some embodiments, the tumor-associated antigen is a tumor-associated antigen selected from the group consisting of CD19, CD33, EpCAM, CEA, PSMA, EGFRvIII, CD133, EGFR, CDH19, ENPP3, DLL3, MSLN, ROR1, HER2, HLAA2, EpHA2, EpHA3, MCSP, CSPG4, NG2, RON, FLT3, BCMA, CD20, FAPα, FRα, CA-9, PDGFRα, PDGFRβ, FSP1, S100A4, ADAM12m, RET, MET, FGFR, INSR, and NTRK. In some embodiments, the tumor-associated antigen includes MAGE-A3, or one or more fragments thereof. In some embodiments, the tumor-associated antigen includes NY-ESO-1, or one or more fragments thereof. In some embodiments, the tumor-associated antigen includes one or more human papillomavirus (HPV) proteins, or fragments thereof. In some embodiments, the tumor-associated antigen includes (i) E6 and E7 proteins, or fragments thereof, of HPV16 and (ii) E6 and E7 proteins, or fragments thereof, of HPV18. In some embodiments, the tumor-associated antigen includes brachyury or one or more fragments thereof. In some embodiments, the tumor-associated antigen includes prostatic acid phosphatase, or one or more fragments thereof.

In some embodiments, the vector further includes a transgene encoding an immune checkpoint inhibitor. In some embodiments, the immune checkpoint inhibitor is selected from the group consisting of OX40 ligand, ICOS ligand, anti-CD47 antibody or antigen-binding fragment thereof, anti-CD40/CD40L antibody or antigen-binding fragment thereof, anti-Lag3 antibody or antigen-binding fragment thereof, anti-CTLA-4 antibody or antigen-binding fragment thereof, anti-PD-L1 antibody or antigen-binding fragment thereof, anti-PD1 antibody or antigen-binding fragment thereof, and anti-Tim-3 antibody or antigen-binding fragment thereof. In some embodiments, the immune checkpoint inhibitor is an anti-PD1 antibody or antigen-binding fragment thereof or an anti-CTLA-4 antibody or antigen-binding fragment thereof. In some embodiments, the immune checkpoint inhibitor is an anti-PD1 antibody or antigen-binding fragment thereof. In some embodiments, the immune checkpoint inhibitor is an anti-CTLA-4 antibody or antigen-binding fragment thereof.

As described above, antibodies or antigen-binding fragments thereof described herein may be full-length antibodies or antibody fragments, such as a monoclonal antibody or antigen-binding fragment thereof, a polyclonal antibody or antigen-binding fragment thereof, a humanized antibody or antigen-binding fragment thereof, a primatized antibody or antigen-binding fragment thereof, a bispecific antibody or antigen-binding fragment thereof, a multi-specific antibody or antigen-binding fragment thereof, a dual-variable immunoglobulin domain, a monovalent antibody or antigen-binding fragment thereof, a chimeric antibody or antigen-binding fragment thereof, a single-chain Fv molecule (scFv), a diabody, a triabody, a nanobody, an antibody-like protein scaffold, a domain antibody, a Fv fragment, a Fab fragment, a F(ab′)₂ molecule, and a tandem scFv (taFv). In some embodiments, the antibody or antigen-binding fragment thereof contains two or more CDRs covalently bound to one another, e.g., by an amide bond, a thioether bond, a carbon-carbon bond, or a disulfide bridge, or by a linker, such as a linker described herein. In some embodiments, the antibody or antigen-binding fragment thereof is a single-chain polypeptide. In some embodiments, the antibody or antigen-binding fragment thereof has an isotype selected from the group consisting of IgG, IgA, IgM, IgD, and IgE.

In some embodiments, the vector further includes a transgene encoding an interleukin. In some embodiments, the interleukin (IL) is selected from the group consisting of IL-1 alpha, IL-1 beta, IL-2, IL-4, IL-7, IL-10, IL-12 p35, IL-12 p40, IL-12 p70, IL-15, IL-18, IL-21, and IL-23. In some embodiments, the interleukin is selected from the group consisting of IL-12 p35, IL-12 p40, and IL-12 p70. In some embodiments, the interleukin is membrane-bound.

In some embodiments, the vector further includes a transgene encoding an interferon. In some embodiments, the interferon is selected from the group consisting of IFN-alpha, IFN-beta, IFN-delta, IFN-epsilon, IFN-tau, IFN-omega, IFN-zeta, and IFN-gamma.

In some embodiments, the vector further includes a transgene encoding a TNF superfamily member protein. In some embodiments, the TNF superfamily member protein is selected from the group consisting of TRAIL, Fas ligand, LIGHT (TNFSF-14), TNF-alpha, and 4-1BB ligand.

In some embodiments, the vector further includes a transgene encoding a cytokine. In some embodiments, the cytokine selected from the group consisting of GM-CSF, FMS-like tyrosine kinase 3 ligand (Flt3 ligand), CD40 ligand, anti-TGF-beta, anti-VEGF-R2, and guanyl adenylate cyclase (cGAS). In some embodiments, the cytokine is Flt3 ligand.

In some embodiments, upon contacting a population of mammalian cells (e.g., human cells, such as human cancer cells) with the nucleic acid or the recombinant orthopoxvirus vector, the cells exhibit increased syncytia formation relative to a population of mammalian cells of the same type contacted with a form of the orthopoxvirus vector that does not include the deletions, as assessed, for instance, by visual inspection using microscopy techniques described herein or known in the art.

In some embodiments, upon contacting a population of mammalian cells (e.g., human cells, such as human cancer cells) with the nucleic acid or the recombinant orthopoxvirus vector, the cells exhibit increased spreading of the orthopoxvirus vector relative to a population of mammalian cells of the same type contacted with a form of the orthopoxvirus vector that does not include the deletions, as assessed, for instance, using plaque-forming assays described herein or known in the art.

In some embodiments, the nucleic acid or the recombinant orthopoxvirus vector exerts an increased cytotoxic effect on a population of mammalian cells (e.g., human cells, such as human cancer cells) relative to that of a form of the orthopoxvirus vector that does not include the deletions, as assessed, for instance, using cell death assays descried herein or known in the art.

In some embodiments, the mammalian cells are from a cell line selected from the group consisting of U2OS, 293, 293T, Vero, HeLa, A549, BHK, BSC40, CHO, OVCAR-8, 786-0, NCI-H23, U251, SF-295, T-47D, SKMEL2, BT-549, SK-MEL-28, MDA-MB-231, SK-OV-3, MCF7, M14, SF-268, CAKI-1, HPAV, OVCAR-4, HCT15, K-562, and HCT-116.

In another aspect, the invention features a packaging cell line that contains the nucleic acid or the recombinant orthopoxvirus vector of any of the aspects or embodiments described herein.

In another aspect, the invention features a method of treating cancer in a mammalian patient by administering a therapeutically effective amount of the nucleic acid or the recombinant orthopoxvirus vector to the patient.

In some embodiments, the mammalian patient is a human patient.

In some embodiments, the cancer is selected from the group consisting of leukemia, lymphoma, liver cancer, bone cancer, lung cancer, brain cancer, bladder cancer, gastrointestinal cancer, breast cancer, cardiac cancer, cervical cancer, uterine cancer, head and neck cancer, gallbladder cancer, laryngeal cancer, lip and oral cavity cancer, ocular cancer, melanoma, pancreatic cancer, prostate cancer, colorectal cancer, testicular cancer, and throat cancer.

In some embodiments, the cancer is selected from the group consisting of acute lymphoblastic leukemia (ALL), acute myeloid leukemia (AML), chronic lymphocytic leukemia (CLL), chronic myelogenous leukemia (CML), adrenocortical carcinoma, AIDS-related lymphoma, primary CNS lymphoma, anal cancer, appendix cancer, astrocytoma, atypical teratoid/rhabdoid tumor, basal cell carcinoma, bile duct cancer, extrahepatic cancer, ewing sarcoma family, osteosarcoma and malignant fibrous histiocytoma, central nervous system embryonal tumors, central nervous system germ cell tumors, craniopharyngioma, ependymoma, bronchial tumors, burkitt lymphoma, carcinoid tumor, primary lymphoma, chordoma, chronic myeloproliferative neoplasms, colon cancer, extrahepatic bile duct cancer, ductal carcinoma in situ (DCIS), endometrial cancer, ependymoma, esophageal cancer, esthesioneuroblastoma, extracranial germ cell tumor, extragonadal germ cell tumor, fallopian tube cancer, fibrous histiocytoma of bone, gastrointestinal carcinoid tumor, gastrointestinal stromal tumors (GIST), testicular germ cell tumor, gestational trophoblastic disease, glioma, childhood brain stem glioma, hairy cell leukemia, hepatocellular cancer, langerhans cell histiocytosis, hodgkin lymphoma, hypopharyngeal cancer, islet cell tumors, pancreatic neuroendocrine tumors, wilms tumor and other childhood kidney tumors, langerhans cell histiocytosis, small cell lung cancer, cutaneous T cell lymphoma, intraocular melanoma, merkel cell carcinoma, mesothelioma, metastatic squamous neck cancer, midline tract carcinoma, multiple endocrine neoplasia syndromes, multiple myeloma/plasma cell neoplasm, myelodysplastic syndromes, nasal cavity and paranasal sinus cancer, nasopharyngeal cancer, neuroblastoma, non-hodgkin lymphoma (NHL), non-small cell lung cancer (NSCLC), epithelial ovarian cancer, germ cell ovarian cancer, low malignant potential ovarian cancer, pancreatic neuroendocrine tumors, papillomatosis, paraganglioma, paranasal sinus and nasal cavity cancer, parathyroid cancer, penile cancer, pharyngeal cancer, pheochromocytoma, pituitary tumor, pleuropulmonary blastoma, primary peritoneal cancer, rectal cancer, retinoblastoma, rhabdomyosarcoma, salivary gland cancer, kaposi sarcoma, rhabdomyosarcoma, sézary syndrome, small intestine cancer, soft tissue sarcoma, throat cancer, thymoma and thymic carcinoma, thyroid cancer, transitional cell cancer of the renal pelvis and ureter, urethral cancer, endometrial uterine cancer, uterine sarcoma, vaginal cancer, vulvar cancer, and Waldenström macroglobulinemia.

In some embodiments, the method further includes administering to the patient an immune checkpoint inhibitor. In some embodiments, the immune checkpoint inhibitor is selected from a group consisting of OX40 ligand, ICOS ligand, anti-CD47 antibody or antigen-binding fragment thereof, anti-CD40/CD40L antibody or antigen-binding fragment thereof, anti-Lag3 antibody or antigen-binding fragment thereof, anti-CTLA-4 antibody or antigen-binding fragment thereof, anti-PD-L1 antibody or antigen-binding fragment thereof, anti-PD1 antibody or antigen-binding fragment thereof, and anti-Tim-3 antibody or antigen-binding fragment thereof In some embodiments, the immune checkpoint inhibitor is an anti-PD1 antibody or antigen-binding fragment thereof or an anti-CTLA-4 antibody or antigen-binding fragment thereof. In some embodiments, the immune checkpoint inhibitor is an anti-PD1 antibody or antigen-binding fragment thereof. In some embodiments, the immune checkpoint inhibitor is an anti-CTLA-4 antibody or antigen-binding fragment thereof.

In some embodiments, the method further includes administering to the patient an interleukin. In some embodiments, the interleukin is selected from a group consisting of IL-alpha, IL-beta, IL-2, IL-4, IL-7, IL-10, IL-12 p35, IL-12 p40, IL-12 p70, IL-15, IL-18, IL-21, and IL-23. In some embodiments, the interleukin is selected from a group consisting of IL-12 p35, IL-12 p40, and IL-12 p70. In some embodiments, the interleukin is membrane-bound.

In some embodiments, the method further includes administering to the patient an interferon. In some embodiments, the interferon is selected from a group consisting of IFN-alpha, IFN-beta, IFN-delta, IFN-epsilon, IFN-tau, IFN-omega, IFN-zeta, and IFN-gamma.

In some embodiments, the method further includes administering to the patient a TNF superfamily member protein. In some embodiments, the TNF superfamily member protein is selected from a group consisting of TRAIL, Fas ligand, LIGHT (TNFSF-14), TNF-alpha, and 4-1BB ligand.

In some embodiments, the method further includes administering to the patient a cytokine. In some embodiments, the cytokine is selected from a group consisting of GM-CSF, Flt3 ligand, CD40 ligand, anti-TGF-beta, anti-VEGF-R2, and cGAS (guanyl adenylate cyclase).

In another aspect, the invention features a kit containing the nucleic acid or vector of any of the aspects or embodiments described herein and a package insert instructing a user of the kit to express the nucleic acid or vector in a host cell.

In another aspect, the invention features a kit containing the nucleic acid or recombinant orthopoxvirus vector of any of the aspects or embodiments described herein and a package insert instructing a user to administer a therapeutically effective amount of the nucleic acid or recombinant orthopoxvirus vector to a mammalian patient (e.g., a human patient) having cancer, thereby treating the cancer.

Definitions

As used herein, the term “about” refers to a value that is no more than 10% above or below the value being described. For example, the term “about 5 nM” indicates a range of from 4.5 nM to 5.5 nM.

As used herein, the term “antibody” (Ab) refers to an immunoglobulin molecule that specifically binds to, or is immunologically reactive with, a particular antigen, and includes polyclonal, monoclonal, genetically engineered and otherwise modified forms of antibodies, including but not limited to chimeric antibodies, humanized antibodies, heteroconjugate antibodies (e.g., bi- tri- and quad-specific antibodies, diabodies, triabodies, and tetrabodies), and antigen-binding fragments of antibodies, including e.g., Fab′, F(ab′)2, Fab, Fv, rlgG, and scFv fragments. Moreover, unless otherwise indicated, the term “monoclonal antibody” (mAb) is meant to include both intact molecules, as well as, antibody fragments (such as, for example, Fab and F(ab′)2 fragments) that are capable of specifically binding to a target protein. Fab and F(ab′)2 fragments lack the Fe fragment of an intact antibody, clear more rapidly from the circulation of the animal, and may have less non-specific tissue binding than an intact antibody (see Wahl et al., J. Nucl. Med. 24:316, 1 983; incorporated herein by reference).

The term “antigen-binding fragment,” as used herein, refers to one or more fragments of an antibody that retain the ability to specifically bind to a target antigen. The antigen-binding function of an antibody can be performed by fragments of a full-length antibody. The antibody fragments can be a Fab, F(ab′)2, scFv, SMIP, diabody, a triabody, an affibody, a nanobody, an aptamer, or a domain antibody. Examples of binding fragments encompassed of the term “antigen-binding fragment” of an antibody include, but are not limited to: (i) a Fab fragment, a monovalent fragment consisting of the VL, VH, CL, and CH1 domains; (ii) a F(ab′)2 fragment, a bivalent fragment comprising two Fab fragments linked by a disulfide bridge at the hinge region; (iii) a Fd fragment consisting of the VH and CH1 domains; (iv) a Fv fragment consisting of the VL and VH domains of a single arm of an antibody, (v) a dAb including VH and VL domains; (vi) a dAb fragment (Ward et al., Nature 341:544-546, 1 989), which consists of a VH domain; (vii) a dAb which consists of a VH or a VL domain; (viii) an isolated complementarity determining region (CDR); and (ix) a combination of two or more isolated CDRs which may optionally be joined by a synthetic linker. Furthermore, although the two domains of the Fv fragment, VL and VH, are coded for by separate genes, they can be joined, using recombinant methods, by a linker that enables them to be made as a single protein chain in which the VL and VH regions pair to form monovalent molecules (known as single-chain Fv (scFv); see, e.g., Bird et al., Science 242:423-426, 1988, and Huston et al., Proc. Natl. Acad. Sci. USA 85:5879-5883, 1988). These antibody fragments can be obtained using conventional techniques known to those of skill in the art, and the fragments can be screened for utility in the same manner as intact antibodies. Antigen-binding fragments can be produced by recombinant DNA techniques, enzymatic or chemical cleavage of intact immunoglobulins, or, in some embodiments, by chemical peptide synthesis procedures known in the art.

As used herein, the term “bispecific antibodies” refers to monoclonal, often human or humanized antibodies that have binding specificities for at least two different antigens.

As used herein, the terms “cell,” “cell line,” and “cell culture” may be used interchangeably. All of these terms also include their progeny, which is any and all subsequent generations. It is understood that all progeny may not be identical due to deliberate or inadvertent mutations.

As used herein, the term “chimeric” antibody refers to an antibody having variable sequences derived from an immunoglobulin of one source organism, such as rat or mouse, and constant regions derived from an immunoglobulin of a different organism (e.g., a human). Methods for producing chimeric antibodies are known in the art. See, e.g., Morrison, 1985, Science 229(4719): 1202-7; Oi et al., 1986, BioTechniques 4:214-221; Gillies et al., 1985, J. Immunol. Methods 125:191-202; U.S. Pat. Nos. 5,807,715; 4,816,567; and 4,816,397; incorporated herein by reference.

As used herein, the term “complementarity determining region” (CDR) refers to a hypervariable region found both in the light chain and the heavy chain variable domains. The more highly conserved portions of variable domains are called the framework regions (FRs). As is appreciated in the art, the amino acid positions that delineate a hypervariable region of an antibody can vary, depending on the context and the various definitions known in the art. Some positions within a variable domain may be viewed as hybrid hypervariable positions in that these positions can be deemed to be within a hypervariable region under one set of criteria while being deemed to be outside a hypervariable region under a different set of criteria. One or more of these positions can also be found in extended hypervariable regions. The variable domains of native heavy and light chains each comprise four framework regions that primarily adopt a β-sheet configuration, connected by three CDRs, which form loops that connect, and in some cases form part of, the β-sheet structure. The CDRs in each chain are held together in close proximity by the FR regions in the order FR1-CDR1-FR2-CDR2-FR3-CDR3-FR4 and, with the CDRs from the other antibody chains, contribute to the formation of the target binding site of antibodies (see Kabat et al., Sequences of Proteins of Immunological Interest (National Institute of Health, Bethesda, Md. 1987; incorporated herein by reference).

As used herein, numbering of immunoglobulin amino acid residues is done according to the immunoglobulin amino acid residue numbering system of Kabat et al, unless otherwise indicated.

As used herein, the terms “conservative mutation,” “conservative substitution,” or “conservative amino acid substitution” refer to a substitution of one or more amino acids for one or more different amino acids that exhibit similar physicochemical properties, such as polarity, electrostatic charge, and steric volume. These properties are summarized for each of the twenty naturally-occurring amino acids in table 1 below. From this table it is appreciated that the conservative amino acid families include (i) G, A, V, L and I; (ii) D and E; (iii) C, Sand T; (iv) H, K and R; (v) N and Q; and (vi) F, Y and W. A conservative mutation or substitution is therefore one that substitutes one amino acid for a member of the same amino acid family (e.g., a substitution of Ser for Thr or Lys for Arg).

TABLE 1 Representative physicochemical properties of naturally occurring amino acids Electrostatic 3 1 Side- character at Letter Letter chain physiological Steric Amino Acid Code Code Polarity pH (7.4) Volume^(†) Alanine Ala A nonpolar neutral small Arginine Arg R polar cationic large Asparagine Asn N polar neutral intermediate Aspartic acid Asp D polar anionic intermediate Cysteine Cys C nonpolar neutral intermediate Glutamic acid Glu E polar anionic intermediate Glutamine Gln Q polar neutral intermediate Glycine Gly G nonpolar neutral small Histidine His H polar Both neutral large and cationic forms in equilibrium at pH 7.4 Isoleucine Ile I nonpolar neutral large Leucine Leu L nonpolar neutral large Lysine Lys K polar cationic large Methionine Met M nonpolar neutral large Phenylalanine Phe F nonpolar neutral large Proline Pro P non-polar neutral intermediate Serine Ser S polar neutral small Threonine Thr T polar neutral intermediate Tryptophan Trp W nonpolar neutral bulky Tyrosine Tyr Y polar neutral large Valine Val V nonpolar neutral intermediate ^(†)based on volume in A³: 50-100 is small, 100-150 is intermediate, 150-200 is large, and >200 is bulky

As used herein, the terms “delete,” “deletion,” and the like refer to modifications to a gene or a regulatory element associated therewith or operatively linked thereto (e.g., a transcription factor-binding site, such as a promoter or enhancer element) that remove the gene or otherwise render the gene nonfunctional. Exemplary deletions, as described herein, include the removal of the entirety of a nucleic acid encoding a gene of interest, from the start codon to the stop codon of the target gene. Other examples of deletions as described herein include the removal of a portion of the nucleic acid encoding the target gene (e.g., one or more codon, or a portion thereof, such as a single nucleotide deletion) such that, upon expression of the partially-deleted target gene, the product is nonfunctional or less functional then a wild-type form of the target gene. Exemplary deletions as described herein include the removal of all or a portion of the regulatory element(s) associated with a gene of interest, such as all or a portion of the promoter and/or enhancer nucleic acids that regulate expression of the target gene.

As used herein, the term “derivatized antibodies” refers to antibodies that are modified by a chemical reaction so as to cleave residues or add chemical moieties not native to an isolated antibody. Derivatized antibodies can be obtained by glycosylation, acetylation, pegylation, phosphorylation, amidation, derivatization by addition of known chemical protecting/blocking groups, proteolytic cleavage, linkage to a cellular ligand or other protein. Any of a variety of chemical modifications can be carried out by known techniques, including, without limitation, specific chemical cleavage, acetylation, formylation, metabolic synthesis of tunicamycin, etc. using established procedures. Additionally, the derivative can contain one or more non-natural amino acids, e.g., using amber suppression technology (see, e.g., U.S. Pat. No. 6,964,859; incorporated herein by reference).

As used herein, the term “diabodies” refers to bivalent antibodies comprising two polypeptide chains, in which each polypeptide chain includes VH and VL domains joined by a linker that is too short (e.g., a linker composed of five amino acids) to allow for intramolecular association of VH and VL domains on the same peptide chain. This configuration forces each domain to pair with a complementary domain on another polypeptide chain so as to form a homodimeric structure. Accordingly, the term “triabodies” refers to trivalent antibodies comprising three peptide chains, each of which contains one VH domain and one VL domain joined by a linker that is exceedingly short (e.g., a linker composed of 1-2 amino acids) to permit intramolecular association of VH and VL domains within the same peptide chain. In order to fold into their native structure, peptides configured in this way typically trimerize so as to position the VH and VL domains of neighboring peptide chains spatially proximal to one another to permit proper folding (see Holliger et al., Proc. Natl. Acad. Sci. USA 90:6444-48, 1993; incorporated herein by reference).

As used herein, a “dual variable domain immunoglobulin” (“DVD-lg”) refers to an antibody that combines the target-binding variable domains of two monoclonal antibodies via linkers to create a tetravalent, dual-targeting single agent. (Gu et al., Meth. Enzymol., 502:25-41, 2012; incorporated by reference herein).

As used herein, the term “endogenous” describes a molecule (e.g., a polypeptide, nucleic acid, or cofactor) that is found naturally in a particular organism (e.g., a human) or in a particular location within an organism (e.g., an organ, a tissue, or a cell, such as a human cell).

As used herein, the term “exogenous” describes a molecule (e.g., a polypeptide, nucleic acid, or cofactor) that is not found naturally in a particular organism (e.g., a human) or in a particular location within an organism (e.g., an organ, a tissue, or a cell, such as a human cell). Exogenous materials include those that are provided from an external source to an organism or to cultured matter extracted there from.

As used herein, the term “framework region” or “FW region” includes amino acid residues that are adjacent to the CDRs. FW region residues may be present in, for example, human antibodies, rodent-derived antibodies (e.g., murine antibodies), humanized antibodies, primatized antibodies, chimeric antibodies, antibody fragments (e.g., Fab fragments), single-chain antibody fragments (e.g., scFv fragments), antibody domains, and bispecific antibodies, among others.

As used herein, the term “heterospecific antibodies” refers to monoclonal, preferably human or humanized, antibodies that have binding specificities for at least two different antigens. Traditionally, the recombinant production of heterospecific antibodies is based on the co-expression of two immunoglobulin heavy chain-light chain pairs, where the two heavy chains have different specificities (Milstein et al., Nature 305:537, 1983). Similar procedures are disclosed, e.g., in WO 93/08829, U.S. Pat. Nos. 6,210,668; 6,193,967; 6,132,992; 6,106,833; 6,060,285; 6,037,453; 6,010,902; 5,989,530; 5,959,084; 5,959,083; 5,932,448; 5,833,985; 5,821,333; 5,807,706; 5,643,759, 5,601,819; 5,582,996, 5,496,549, 4,676,980, WO 91/00360, WO 92/00373, EP 03089, Traunecker et al., EMBO J. 10:3655 (1991), Suresh et al., Methods in Enzymology 121:21 0 (1986); incorporated herein by reference. Heterospecific antibodies can include Fc mutations that enforce correct chain association in multi-specific antibodies, as described by Klein et al, mAbs 4(6):653-663, 2012; incorporated herein by reference.

As used herein, the term “human antibody” refers to an antibody in which substantially every part of the protein (e.g., CDR, framework, C_(L), C_(H) domains (e.g., C_(H)1, C_(H)2, C_(H)3), hinge, (V_(L), V_(H))) is substantially non-immunogenic in humans, with only minor sequence changes or variations. A human antibody can be produced in a human cell (e.g., by recombinant expression), or by a non-human animal or a prokaryotic or eukaryotic cell that is capable of expressing functionally rearranged human immunoglobulin (e.g., heavy chain and/or light chain) genes. Further, when a human antibody is a single-chain antibody, it can include a linker peptide that is not found in native human antibodies. For example, an Fv can comprise a linker peptide, such as two to about eight glycine or other amino acid residues, which connects the variable region of the heavy chain and the variable region of the light chain. Such linker peptides are considered to be of human origin. Human antibodies can be made by a variety of methods known in the art including phage display methods using antibody libraries derived from human immunoglobulin sequences. See U.S. Pat. Nos. 4,444,887 and 4,716,111; and PCT publications WO 1998/46645; WO 1998/50433; WO 1998/24893; WO 1998/16654; WO 1996/34096; WO 1996/33735; and WO 1991/10741; incorporated herein by reference. Human antibodies can also be produced using transgenic mice that are incapable of expressing functional endogenous immunoglobulins, but which can express human immunoglobulin genes. See, e.g., PCT publications WO 98/24893; WO 92/01047; WO 96/34096; WO 96/33735; U.S. Pat. Nos. 5,413,923; 5,625,126; 5,633,425; 5,569,825; 5,661,016; 5,545,806; 5,814,318; 5,885,793; 5,916,771; and 5,939,598; incorporated by reference herein.

As used herein, the term “humanized” antibodies refers to forms of non-human (e.g., murine) antibodies that are chimeric immunoglobulins, immunoglobulin chains or fragments thereof (such as Fv, Fab, Fab′, F(ab′)₂ or other target-binding subdomains of antibodies) which contain minimal sequences derived from non-human immunoglobulin. In general, the humanized antibody will comprise substantially all of at least one, and typically two, variable domains, in which all or substantially all of the CDR regions correspond to those of a non-human immunoglobulin. All or substantially all of the FR regions may also be those of a human immunoglobulin sequence. The humanized antibody can also comprise at least a portion of an immunoglobulin constant region (Fc), typically that of a human immunoglobulin consensus sequence. Methods of antibody humanization are known in the art. See, e.g., Riechmann et al., Nature 332:323-7, 1988; U.S. Pat. Nos. 5,530,101; 5,585,089; 5,693,761; 5,693,762; and U.S. Pat. No. 6,180,370 to Queen et al; EP239400; PCT publication WO 91/09967; U.S. Pat. No. 5,225,539; EP592106; and EP519596; incorporated herein by reference.

As used herein, the term “monoclonal antibody” refers to an antibody that is derived from a single clone, including any eukaryotic, prokaryotic, or phage clone, and not the method by which it is produced.

As used herein, the term “multi-specific antibodies” refers to antibodies that exhibit affinity for more than one target antigen. Multi-specific antibodies can have structures similar to full immunoglobulin molecules and include Fc regions, for example IgG Fc regions. Such structures can include, but not limited to, IgG-Fv, lgG-(scFv)2, DVD-lg, (scFv)2-(scFv)2-Fc and (scFv)2-Fc-(scFv)2. In case of lgG-(scFv)2, the scFv can be attached to either the N-terminal or the C-terminal end of either the heavy chain or the light chain. Exemplary multi-specific molecules have been reviewed by Kontermann, 2012, mAbs 4(2):182-197, Yazaki et al., 2013, Protein Engineering, Design & Selection 26(3):1 87-1 93, and Grote et al., 2012, in Proetzel & Ebersbach (eds.), Antibody Methods and Protocols, Methods in Molecular Biology vol. 901, chapter 16:247-263; incorporated herein by reference. Exemplary multi-specific molecules that lack Fc regions and into which antibodies or antibody fragments can be incorporated include scFv dimers (diabodies), trimers (triabodies) and tetramers (tetrabodies), Fab dimers (conjugates by adhesive polypeptide or protein domains) and Fab trimers (chemically conjugated), are described by Hudson and Souriau, 2003, Nature Medicine 9:129-134; incorporated herein by reference.

As used herein, the term “percent(%) sequence identity” refers to the percentage of amino acid (or nucleic acid) residues of a candidate sequence that are identical to the amino acid (or nucleic acid) residues of a reference sequence after aligning the sequences and introducing gaps, if necessary, to achieve the maximum percent sequence identity (e.g., gaps can be introduced in one or both of the candidate and reference sequences for optimal alignment and non-homologous sequences can be disregarded for comparison purposes). Alignment for purposes of determining percent sequence identity can be achieved in various ways that are within the skill in the art, for instance, using publicly available computer software, such as BLAST, ALIGN, or Megalign (ONASTAR) software. Those skilled in the art can determine appropriate parameters for measuring alignment, including any algorithms needed to achieve maximal alignment over the full length of the sequences being compared. For example, a reference sequence aligned for comparison with a candidate sequence may show that the candidate sequence exhibits from 50% to 100% sequence identity across the full length of the candidate sequence or a selected portion of contiguous amino acid (or nucleic acid) residues of the candidate sequence. The length of the candidate sequence aligned for comparison purposes may be, for example, at least 30%, (e.g., 30%, 40, 50%, 60%, 70%, 80%, 90%, or 100%) of the length of the reference sequence. When a 5 position in the candidate sequence is occupied by the same amino acid residue as the corresponding position in the reference sequence, then the molecules are identical at that position.

As used herein, the term “primatized antibody” refers to an antibody comprising framework regions from primate-derived antibodies and other regions, such as CDRs and constant regions, from antibodies of a non-primate source. Methods for producing primatized antibodies are known in the art. See e.g., U.S. Pat. Nos. 5,658,570; 5,681,722; and 5,693,780; incorporated herein by reference.

As used herein, the term “operatively linked” in the context of a polynucleotide fragment is intended to mean that the two polynucleotide fragments are joined such that the amino acid sequences encoded by the two polynucleotide fragments remain in-frame.

As used herein, the terms “regulatory element” and the like refer to promoters, enhancers, and other expression control elements (e.g., polyadenylation signals) that control the transcription or translation of the antibody chain genes. Such regulatory sequences are described, for example, in Goeddel, Gene Expression Technology: Methods in Enzymology 185 (Academic Press, San Diego, Calif., 1990); incorporated herein by reference.

As used herein, the terms “subject” and “patient” refer to an organism that receives treatment for a particular disease or condition as described herein (such as cancer or an infectious disease). Examples of subjects and patients include mammals, such as humans, receiving treatment for diseases or conditions, for example, cell proliferation disorders, such as cancer.

As used herein, the term “scFv” refers to a single-chain Fv antibody in which the variable domains of the heavy chain and the light chain from an antibody have been joined to form one chain. scFv fragments contain a single polypeptide chain that includes the variable region of an antibody light chain (VL) (e.g., CDR-L1, CDR-L2, and/or CDR-L3) and the variable region of an antibody heavy chain (VH) (e.g., CDR-H1, CDR-H2, and/or CDR-H3) separated by a linker. The linker that joins the VL and VH regions of a scFv fragment can be a peptide linker composed of proteinogenic amino acids. Alternative linkers can be used to so as to increase the resistance of the scFv fragment to proteolytic degradation (e.g., linkers containing D-amino acids), in order to enhance the solubility of the scFv fragment (e.g., hydrophilic linkers such as polyethylene glycol-containing linkers or polypeptides containing repeating glycine and serine residues), to improve the biophysical stability of the molecule (e.g., a linker containing cysteine residues that form intramolecular or intermolecular disulfide bonds), or to attenuate the immunogenicity of the scFv fragment (e.g., linkers containing glycosylation sites). scFv molecules are known in the art and are described, e.g., in U.S. Pat. No. 5,892,019, Flo et al., (Gene 77:51, 1989); Bird et al., (Science 242:423, 1988); Pantoliano et al., (Biochemistry 30:10117, 1991); Milenic et al., (Cancer Research 51:6363, 1991); and Takkinen et al., (Protein Engineering 4:837, 1991). The VL and VH domains of a scFv molecule can be derived from one or more antibody molecules. It will also be understood by one of ordinary skill in the art that the variable regions of the scFv molecules of the invention can be modified such that they vary in amino acid sequence from the antibody molecule from which they were derived. For example, in some embodiments, nucleotide or amino acid substitutions leading to conservative substitutions or changes at amino acid residues can be made (e.g., in CDR and/or framework residues). Alternatively or in addition, mutations are made to CDR amino acid residues to optimize antigen binding using art recognized techniques. scFv fragments are described, for example, in WO 2011/084714; incorporated herein by reference.

As used herein, the phrase “specifically binds” refers to a binding reaction which is determinative of the presence of an antigen in a heterogeneous population of proteins and other biological molecules that is recognized, e.g., by an antibody or antigen-binding fragment thereof, with particularity. An antibody or antigen-binding fragment thereof that specifically binds to an antigen may bind to the antigen with a K_(D) of less than 100 nM. For example, an antibody or antigen-binding fragment thereof that specifically binds to an antigen may bind to the antigen with a K_(D) of up to 100 nM (e.g., between 1 pM and 100 nM). An antibody or antigen-binding fragment thereof that does not exhibit specific binding to a particular antigen or epitope thereof may exhibit a K_(D) of greater than 100 nM (e.g., greater than 500 nm, 1 μM, 100 μM, 500 μM, or 1 mM) for that particular antigen or epitope thereof. A variety of immunoassay formats may be used to select antibodies specifically immunoreactive with a particular protein or carbohydrate. For example, solid-phase ELISA immunoassays are routinely used to select antibodies specifically immunoreactive with a protein or carbohydrate. See, Harlow & Lane, Antibodies, A Laboratory Manual, Cold Spring Harbor Press, New York (1988) and Harlow & Lane, Using Antibodies, A Laboratory Manual, Cold Spring Harbor Press, New York (1999), for a description of immunoassay formats and conditions that can be used to determine specific immunoreactivity.

As used herein, the term “transfection” refers to any of a wide variety of techniques commonly used for the introduction of exogenous DNA into a prokaryotic or eukaryotic host cell, e.g., electroporation, lipofection, calcium-phosphate precipitation, DEAE-dextran transfection and the like.

As used herein, the terms “treat” or “treatment” refer to therapeutic treatment, in which the object is to prevent or slow down (lessen) an undesired physiological change or disorder, such as the progression of a cell proliferation disorder, such as cancer. Beneficial or desired clinical results include, but are not limited to, alleviation of symptoms, diminishment of extent of disease, stabilized (i.e., not worsening) state of disease, delay or slowing of disease progression, amelioration or palliation of the disease state, and remission (whether partial or total), whether detectable or undetectable. Those in need of treatment include those already with the condition or disorder, as well as those prone to have the condition or disorder or those in which the condition or disorder is to be prevented.

As used herein, the term “vector” refers to a nucleic acid vector, e.g., a DNA vector, such as a plasmid, a RNA vector, virus or other suitable replicon (e.g., viral vector). A variety of vectors have been developed for the delivery of polynucleotides encoding exogenous proteins into a prokaryotic or eukaryotic cell. Examples of such expression vectors are disclosed in, e.g., WO 1994/11026; incorporated herein by reference. Expression vectors of the invention may contain one or more additional sequence elements used for the expression of proteins and/or the integration of these polynucleotide sequences into the genome of a host cell, such as a mammalian cell (e.g., a human cell). Exemplary vectors that can be used for the expression of antibodies and antibody fragments described herein include plasmids that contain regulatory sequences, such as promoter and enhancer regions, which direct gene transcription. Vectors may contain nucleic acids that modulate the rate of translation of a target gene or that improve the stability or nuclear export of the mRNA that results from gene transcription. These sequence elements may include, e.g., 5′ and 3′ untranslated regions, an internal ribosomal entry site (IRES), and polyadenylation signal site in order to direct efficient transcription of the gene carried on the expression vector. The vectors described herein may also contain a polynucleotide encoding a marker for selection of cells that contain such a vector. Examples of a suitable marker include genes that encode resistance to antibiotics, such as ampicillin, chloramphenicol, kanamycin, or nourseothricin.

As used herein, the term “VH” refers to the variable region of an immunoglobulin heavy chain of an antibody, including the heavy chain of an Fv, scFv, or Fab. References to “VL” refer to the variable region of an immunoglobulin light chain, including the light chain of an Fv, scFv, dsFv or Fab. Antibodies (Abs) and immunoglobulins (Igs) are glycoproteins having the same structural characteristics. While antibodies exhibit binding specificity to a specific target, immunoglobulins include both antibodies and other antibody-like molecules which lack target specificity. Native antibodies and immunoglobulins are usually heterotetrameric glycoproteins of about 1 50,000 Daltons, composed of two identical light (L) chains and two identical heavy (H) chains. Each heavy chain of a native antibody has at the amino terminus a variable domain (VH) followed by a number of constant domains. Each light chain of a native antibody has a variable domain at the amino terminus (VL) and a constant domain at the carboxy terminus.

Gene Definitions

As used herein, “C2L” refers to a orthopoxvirus gene, such as a gene that encodes a kelch-like protein. Non-limiting examples of protein sequences encoding the C2L gene are listed in tables 31-35 below. The term “C2L” may also include fragments or variants of the proteins listed in the tables below, or homologous genes from another orthopoxvirus strain.

As used herein, “C1L” refers to a orthopoxvirus gene. Non-limiting examples of protein sequences encoding the C1L gene are listed in tables 31-35 below. The term “C1L” may also include fragments or variants of the proteins listed in the tables below, or homologous genes from another orthopoxvirus strain.

As used herein, “N1L” refers to a orthopoxvirus gene, such as a gene that encodes a BCL-2 inhibitor. Non-limiting examples of protein sequences encoding the N1L gene are listed in tables 31-35 below. The term “N1L” may also include fragments or variants of the proteins listed in the tables below, or homologous genes from another orthopoxvirus strain.

As used herein, “N2L” refers to a orthopoxvirus gene, such as a gene that encodes a TLR signaling inhibitor. Non-limiting examples of protein sequences encoding the N2L gene are listed in tables 31-35 below. The term “N2L” may also include fragments or variants of the proteins listed in the tables below, or homologous genes from another orthopoxvirus strain.

As used herein, “ML” refers to a orthopoxvirus gene, such as a gene that encodes an Ankyrin repeat protein. Non-limiting examples of protein sequences encoding the M1L gene are listed in tables 31-35 below. The term “M1L” may also include fragments or variants of the proteins listed in the tables below, or homologous genes from another orthopoxvirus strain.

As used herein, “M2L” refers to a orthopoxvirus gene, such as a gene that encodes an NF-κB inhibitor. Non-limiting examples of protein sequences encoding the M2L gene are listed in tables 31-35 below. The term “M2L” may also include fragments or variants of the proteins listed in the tables below, or homologous genes from another orthopoxvirus strain.

As used herein, “K1L” refers to a orthopoxvirus gene, such as a gene that encodes an NF-κB inhibitor. Non-limiting examples of protein sequences encoding the K1L gene are listed in tables 31-35 below. The term “K1 L” may also include fragments or variants of the proteins listed in the tables below, or homologous genes from another orthopoxvirus strain.

As used herein, “K2L” refers to a orthopoxvirus gene, such as a gene that encodes an Ankyrin repeat protein. Non-limiting examples of protein sequences encoding the K2L gene are listed in tables 31-35 below. The term “K2L” may also include fragments or variants of the proteins listed in the tables below, or homologous genes from another orthopoxvirus strain.

As used herein, “K3L” refers to a orthopoxvirus gene, such as a gene that encodes a PKR inhibitor. Non-limiting examples of protein sequences encoding the K3L gene are listed in tables 31-35 below. The term “K3L” may also include fragments or variants of the proteins listed in the tables below, or homologous genes from another orthopoxvirus strain.

As used herein, “K4L” refers to a orthopoxvirus gene, such as a gene that encodes a pbospholipase-D. Non-limiting examples of protein sequences encoding the K4L gene are listed in tables 31-35 below. The term “K4L” may also include fragments or variants of the proteins listed in the tables below, or homologous genes from another orthopoxvirus strain.

As used herein, “K5L” refers to a orthopoxvirus gene, such as a gene that encodes a monoglyceride lipase. Non-limiting examples of protein sequences encoding the K5L gene are listed in tables 31-35 below. The term “K5L” may also include fragments or variants of the proteins listed in the tables below, or homologous genes from another orthopoxvirus strain.

As used herein, “K6L” refers to a orthopoxvirus gene, such as a gene that encodes a monoglyceride lipase. Non-limiting examples of protein sequences encoding the K6L gene are listed in tables 31-35 below. The term “K6L” may also include fragments or variants of the proteins listed in the tables below, or homologous genes from another orthopoxvirus strain.

As used herein, “K7R” refers to a orthopoxvirus gene, such as a gene that encodes an NF-κB inhibitor. Non-limiting examples of protein sequences encoding the K7R gene are listed in tables 31-35 below. The term “K7R” may also include fragments or variants of the proteins listed in the tables below, or homologous genes from another orthopoxvirus strain.

As used herein, “F1L” refers to a orthopoxvirus gene, such as a gene that encodes a caspase-9 inhibitor. Non-limiting examples of protein sequences encoding the F1L gene are listed in tables 31-35 below. The term “F1L” may also include fragments or variants of the proteins listed in the tables below, or homologous genes from another orthopoxvirus strain.

As used herein, “F2L” refers to a orthopoxvirus gene, such as a gene that encodes a dUTPase. Non-limiting examples of protein sequences encoding the F2L gene are listed in tables 31-35 below. The term “F2L” may also include fragments or variants of the proteins listed in the tables below, or homologous genes from another orthopoxvirus strain.

As used herein, “F3L” refers to a orthopoxvirus gene, such as a gene that encodes a kelch-like protein. Non-limiting examples of protein sequences encoding the F3L gene are listed in tables 31-35 below. The term “F1L” may also include fragments or variants of the proteins listed in the tables below, or homologous genes from another orthopoxvirus strain.

As used herein, “B14R” refers to a orthopoxvirus gene. Non-limiting examples of protein sequences encoding the B14R gene are listed in tables 36-40 below. The term “B14R” may also include fragments or variants of the proteins listed in the tables below, or homologous genes from another orthopoxvirus strain.

As used herein, “B15R” refers to a orthopoxvirus gene. Non-limiting examples of protein sequences encoding the B15R gene are listed in tables 36-40 below. The term “B15R” may also include fragments or variants of the proteins listed in the tables below, or homologous genes from another orthopoxvirus strain.

As used herein, “B16R” refers to a orthopoxvirus gene, such as a gene that encodes a IL-1-beta inhibitor. Non-limiting examples of protein sequences encoding the B16R gene are listed in tables 31-35 below. The term “B16R” may also include fragments or variants of the proteins listed in the tables below, or homologous genes from another orthopoxvirus strain.

As used herein, “B17L” refers to a orthopoxvirus gene. Non-limiting examples of protein sequences encoding the B17L gene are listed in tables 36-40 below. The term “B17L” may also include fragments or variants of the proteins listed in the tables below, or homologous genes from another orthopoxvirus strain.

As used herein, “B18R” refers to a orthopoxvirus gene, such as a gene that encodes an Ankyrin repeat protein. Non-limiting examples of protein sequences encoding the B18R gene are listed in tables 36-40 below. The term “B18R” may also include fragments or variants of the proteins listed in the tables below, or homologous genes from another orthopoxvirus strain.

As used herein, “B19R” refers to a orthopoxvirus gene, such as a gene that encodes a IFN-alpha-beta-receptor-like secreted glycoprotein. Non-limiting examples of protein sequences encoding the B19R gene are listed in tables 36-40 below. The term “B19R” may also include fragments or variants of the proteins listed in the tables below, or homologous genes from another orthopoxvirus strain.

As used herein, “B20R” refers to a orthopoxvirus gene, such as a gene that encodes an Ankyrin repeat protein. Non-limiting examples of protein sequences encoding the B20R gene are listed in tables 36-40 below. The term “B20R” may also include fragments or variants of the proteins listed in the tables below, or homologous genes from another orthopoxvirus strain.

As used herein, “B8R” refers to a orthopoxvirus gene, such as a gene that encodes a secreted protein with homology to the gamma interferon (IFN-γ). A nonlimiting example of a protein sequence encoded by an exemplary B8R gene in a Copenhagen strain of the vaccinia virus is given in UniProtKB database entry P21004 and is reproduced below:

(SEQ ID NO: 209) MRYIIILAVLFINSIHAKITSYKFESVNFDSKIEWTGDGLYNISLKNYGI KTWQTMYTNVPEGTYDISAFPKNDFVSFWVKFEQGDYKVEEYCTGLCVEV KIGPPTVTLTEYDDHINLYIEHPYATRGSKKIPIYKRGDMCDIYLLYTAN FTFGDSEEPVTYDIDDYDCTSTGCSIDFATTEKVCVTAQGATEGFLEKIT PWSSEVCLTPKKNVYTCAIRKEDVPNFKDKMARVIKRKFNKQSQSYLTKF LGSTSNDVTTFLSMLNLTKYS The term “B8R” may also include fragments or variants of the proteins listed above, or homologous genes from another orthopoxvirus strain. Variants include without limitation those sequences having 85 percent or greater identity to the sequences disclosed herein.

BRIEF DESCRIPTION OF THE FIGURES

FIG. 1 shows the phylogenetic analysis of 59 poxvirus strains, including the Orthopoxvirus virus strains.

FIG. 2 shows the abundance of different viral strains after passaging 5 Vaccinia viruses in different tumor types.

FIG. 3 shows the ability to replicate in various different patient tumor cores of Vaccinia wild-type strains.

FIG. 4 shows plaque size measurements of different Vaccinia wild-type strains.

FIG. 5A shows the number of TTAA sites across 1 kb regions in Vaccinia Copenhagen genome.

FIG. 5B shows the frequency of Transposon Insertions across Vaccinia Copenhagen genome. Each dot represents a transposon knockout of a particular gene. The position of the dot on the y-axis is determined by the frequency of the knockout.

FIG. 5C shows Poxvirus gene conservation in 59 viruses. Higher conservation indicates the gene is present in a larger amount of species.

FIG. 6 shows the frequency of various transposon knockouts after passaging in permissive cancer cells.

FIG. 7 shows plaque size measurements of purified transposons.

FIG. 8 shows the genomic structure of a 5p deletion (CopMD5p) and a 3p deletion (CopMD3p). CopMD5p and CopMD3p were crossed to generate CopMD5p3p.

FIG. 9 shows a heatmap showing cancer cell death following infection with either Copenhagen or CopMD5p3p at various doses.

FIG. 10 shows the growth curves of Copenhagen and CopMD5p3p replication in 4 different cancer cell lines.

FIG. 11 shows the ability of Copenhagen and CopMD5p3p to replicate in patient ex vivo samples as shown by titering.

FIG. 12 shows that the modified CopMD5p3p virus forms different plaques than the parental virus. CopMD5p3p plaques are much clearer in the middle and we can see syncytia (cell fusion).

FIG. 13 shows CopMD5p3p induces syncytia (cell fusion) in 786-0 cells.

FIG. 14 shows that CopMD5p3p is able to control tumour growth similarly to Copenhagen wild-type but does not cause weight loss.

FIG. 15 shows that CopMD5p3p does not cause pox lesion formation when compared to two other Vaccinia strains (Copenhagen and Wyeth) harboring the oncolytic knockout of thymidine kinase.

FIG. 16 shows the IVIS bio-distribution of Vaccinia after systemic administration in nude CD-1 mice. Luciferase encoding CopMD5p3p (TK KO) is tumor specific and does not replicate in off target tissues.

FIG. 17 shows the bio-distribution of Vaccinia after systemic administration. CopMD5p3p replicates similarly to other oncolytic Vaccinia in the tumour but replicates less in off target tissues/organs.

FIG. 18 shows the immunogenicity of Vaccinia in Human PBMCs. The ability of CopMD5p3p to induce human innate immune cell activation is stronger than that of wild-type Copenhagen. Data was acquired through flow cytometric analysis.

FIG. 19 shows the immunogenicity of Vaccinia in Mouse Splenocytes. The ability of CopMD5p3p to induce mouse innate immune cell activation is stronger than that of Copenhagen. Data was acquired through flow cytometric analysis.

FIG. 20 shows the immunogenicity of Vaccinia in Human cells. The ability of CopMD5p3p to activate NF-kB immune transcription factor is stronger than that of Copenhagen or VVdd but similar to that of MG-1. Data shown are western blots.

FIG. 21 shows the synergy with immune checkpoint inhibitor Anti-CTLA-4 (100 μg) in an aggressive melanoma model (B16-F10). In vivo efficacy measured by survival in an immune competent murine model treated with Vaccinia and Immune Checkpoint Inhibitors Anti-CTLA4.

FIG. 22 shows the synergy with immune checkpoint inhibitor Anti-CTLA4 (100 μg). In vivo efficacy measured by tumor growth (top row) and survival (bottom row) in an immune competent murine model treated with Vaccinia and Immune Checkpoint Inhibitor Anti-CTLA4. CopMD5p3p (left column) is compared to oncolytic Copenhagen TK KO (right column).

FIG. 23 shows the synergy with immune checkpoint inhibitor Anti-PD1 (100 μg). In vivo efficacy measured by tumor growth (top row) and survival (bottom row) in an immune competent murine model treated with Vaccinia and Immune Checkpoint Inhibitor Anti-PD1. CopMD5p3p (left column) is compared to oncolytic Copenhagen TK KO (right column).

FIG. 24 shows the synergy with immune checkpoint inhibitor Anti-PD1 (25 μg) and Anti-CTLA-4 (25 μg). In vivo efficacy measured by tumor growth (top row) and survival (bottom row) in an immune competent murine model treated with Vaccinia and Immune Checkpoint Inhibitors Anti-PD1 and Anti-CTLA4. CopMD5p3p (left column) is compared to oncolytic Copenhagen TK KO (right column).

FIG. 25 shows a schematic representation of the homologous recombination targeting strategy employed to generate denovo 5p (left) and 3p (right) major deletions in various vaccinia strains.

FIG. 26 shows the ability of wild-type Copenhagen vaccinia virus and several modified Copenhagen vaccinia virions to proliferate in various cell lines.

FIG. 27 shows the cytotoxic effects of wild-type Copenhagen vaccinia virus and several modified Copenhagen vaccinia virions on various cell lines, as assessed by coomassie blue (upper panel) and an Alamar Blue assay (lower panel). The order of strains listed for each cell line along the x-axis of the chart shown in the lower panel is as follows: from left to right, CopMD5p, CopMD5p3p, CopMD3p, and CopWT.

FIG. 28 shows the distribution of wild-type Copenhagen vaccinia virus and several modified Copenhagen vaccinia virions upon administration to mice.

FIG. 29 shows the ability of wild-type Copenhagen vaccinia virus and several modified Copenhagen vaccinia virions to activate Natural Killer (NK) cells and stimulate an immune response.

FIG. 30 shows the ability of wild-type Copenhagen vaccinia virus and several modified Copenhagen vaccinia virions to enhance NK cell-mediated degranulation against HT29 cells, a measure of NK cell activity and stimulate an immune response.

FIG. 31 shows the ability of wild-type Copenhagen vaccinia virus and several modified Copenhagen vaccinia virions to prime T-cells to initiate an anti-tumor immune response.

FIG. 32 shows the ability of wild-type Copenhagen vaccinia virus and several modified Copenhagen vaccinia virions to spread to distant locations from the initial point of infection.

FIG. 33 shows the ability of wild-type Copenhagen vaccinia virus and several modified Copenhagen vaccinia virions to form plaques, a measure of viral proliferation.

FIG. 34 shows the ability of wild-type Copenhagen vaccinia virus and several modified Copenhagen vaccinia virions to form plaques in 786-O cells.

FIG. 35 shows the percentage of genes deleted in CopMD5p3p in various poxvirus genomes.

FIG. 36 shows infection of normal versus cancer cell lines of SKV-B8R+ virus.

FIG. 37 shows SKV-B8R+ does not impair interferon signaling.

FIG. 38 shows SKV (CopMD5p3-B8R−) has similar efficacy in tumour control compared to SKV-B8R+.

FIG. 39 shows SKV engineered to express 2 immunotherapeutuic transgenes and an antibody.

FIG. 40 shows SKV expressing murine IL-12 p35 membrane bound has greater efficacy in controlling murine tumours.

FIG. 41 shows major double deletions engineered in various vaccinia strains enhance cancer cell killing in vitro.

FIG. 42 shows the phenotypic characterization of HeLa cells infected with various vaccinia strains.

FIG. 43 shows 5p3p vaccinia strains do not induce weight loss compared to wildtype strains.

FIG. 44 shows 5p3p vaccinia strains do not induce pox lesions compared to wildtype strains.

DETAILED DESCRIPTION

The present invention features genetically modified orthopoxviruses, such as vaccinia viruses (e.g. Copenhagen, Western Reserve, Wyeth, Lister, EM63, ACAM2000, CV-1, modified vaccinia Ankara (MVA), Dairen I, GLV-1h68, IHD-J, L-IVP, LC16m8, LC16mO, Tashkent, Tian Tan, and WAU86/88-1 viruses), as well as the use of the same for the treatment of various cancers. The invention is based in part on the surprising discovery that orthopoxviruses, such as Copenhagen, Western Reserve, Wyeth, Lister, EM63, ACAM2000, CV-1, modified vaccinia Ankara (MVA), Dairen I, GLV-1h68, IHD-J, L-IVP, LC16m8, LC16mO, Tashkent, Tian Tan, and WAU86/88-1 viruses, exhibit markedly improved oncolytic activity, replication in tumors, infectivity, immune evasion, tumor persistence, capacity for incorporation of exogenous DNA sequences, and amenability for large scale manufacturing when the viruses are engineered to contain deletions in one or more, or all, of the C2L, C1L, N1L, N2L, M1L, M2L, K1L, K2L, K3L, K4L, K5L, K6L, K7R, F1L, F2L, F3L, B14R, B15R, B16R, B17L, B18R, B19R, B20R, K ORF A, K ORF B, B ORF E, B ORF F, B ORF G, B21R, B22R, B23R, B24R, B25R, B26R, B27R, B28R, and B29R genes. In various embodiments of the invention, the modified orthopox viruses contain a deletion of the B8R gene. While inactive in mice, the B8R gene neutralizes antiviral activity of human IFN-γ. In various embodiments, at least one transgene is subsequently inserted into locus of the B8R gene (now deleted) through a homologous recombination targeting strategy. In various embodiments, the modified orthopoxvirus expresses at least one of three transgenes: IL-12-TM, FLT3-L and anti-CTLA4 antibody.

The orthopoxviruses described herein can be administered to a patient, such as a mammalian patient (e.g., a human patient) to treat a variety of cell proliferation disorders, including a wide range of cancers. The sections that follow describe orthopoxviruses and genetic modifications thereto, as well as methods of producing and propagating genetically modified orthopoxviruses and techniques for administering the same to a patient.

Poxvirus

Generally, a poxvirus viral particle is oval or brick-shaped, measuring some 200-400 nm long. The external surface is ridged in parallel rows, sometimes arranged helically. Such particles are extremely complex, containing over 100 distinct proteins. The extracellular forms contain two membranes (EEV: extracellular enveloped virions), whereas intracellular particles only have an inner membrane (IMV: intracellular mature virions). The outer surface is composed of lipid and protein that surrounds the core, which is composed of a tightly compressed nucleoprotein. Antigenically, poxviruses are also very complex, inducing both specific and cross-reacting antibodies. There are at least ten enzymes present in the particle, mostly concerned with nucleic acid metabolism/genome replication.

The genome of the wild-type poxvirus is linear double-stranded DNA of 130-300 Kbp. The ends of the genome have a terminal hairpin loop with several tandem repeat sequences. Several poxvirus genomes have been sequenced, with most of the essential genes being located in the central part of the genome, while non-essential genes are located at the ends. There are about 250 genes in the poxvirus genome. Replication takes place in the cytoplasm, as the virus is sufficiently complex to have acquired all the functions necessary for genome replication. There is some contribution by the cell, but the nature of this contribution is not clear. However, even though poxvirus gene expression and genome replication occur in enucleated cells, maturation is blocked, indicating some role by the cell.

Once into the cell cytoplasm, gene expression is carried out by viral enzymes associated with the core. Expression is divided into 2 phases: early genes: which represent about of 50% genome, and are expressed before genome replication, and late genes, which are expressed after genome replication. The temporal control of expression is provided by the late promoters, which are dependent on DNA replication for activity. Genome replication is believed to involve self-priming, leading to the formation of high molecular weight concatemers, which are subsequently cleaved and repaired to make virus genomes. Viral assembly occurs in the cytoskeleton and probably involves interactions with the cytoskeletal proteins (e.g., actin-binding proteins). Inclusions form in the cytoplasm that mature into virus particles. Cell to cell spread may provide an alternative mechanism for spread of infection. Overall, replication of this large, complex virus is rather quick, taking just 12 hours on average. At least nine different poxviruses cause disease in humans, but variola virus and vaccinia are the best known. Variola strains are divided into variola major (25-30% fatalities) and variola minor (same symptoms but less than 1% death rate). Infection with both viruses occurs naturally by the respiratory route and is systemic, producing a variety of symptoms, but most notably with variola characteristic pustules and scarring of the skin.

Vaccinia Virus as a Species of Orthopoxvirus

Vaccinia virus is a large, complex enveloped virus having a linear double-stranded DNA genome of about 190K by and encoding for approximately 250 genes. Vaccinia is well-known for its role as a vaccine that eradicated smallpox. Post-eradication of smallpox, scientists have been exploring the use of vaccinia as a tool for delivering genes into biological tissues (gene therapy and genetic engineering). Vaccinia virus is unique among DNA viruses as it replicates only in the cytoplasm of the host cell. Therefore, the large genome is required to code for various enzymes and proteins needed for viral DNA replication. During replication, vaccinia produces several infectious forms, which differ in their outer membranes: the intracellular mature virion (IMV), the intracellular enveloped virion (IEV), the cell-associated enveloped virion (CEV), and the extracellular enveloped virion (EEV). IMV is the most abundant infectious form and is thought to be responsible for spread between hosts. On the other hand, the CEV is believed to play a role in cell-to-cell spread and the EEV is thought to be important for long-range dissemination within the host organism.

Vaccinia virus is closely related to the virus that causes cowpox. The precise origin of vaccinia is unknown, but the most common view is that vaccinia virus, cowpox virus, and variola virus (the causative agent for smallpox) were all derived from a common ancestral virus. There is also speculation that vaccinia virus was originally isolated from horses. A vaccinia virus infection is mild and typically asymptomatic in healthy individuals, but it may cause a mild rash and fever, with an extremely low rate of fatality. An immune response generated against a vaccinia virus infection protects that person against a lethal smallpox infection. For this reason, vaccinia virus was used as a live-virus vaccine against smallpox. The vaccinia virus vaccine is safe because it does not contain the smallpox virus, but occasionally certain complications and/or vaccine adverse effects may arise, especially if the vaccine is immunocompromised.

Exemplary strains of the vaccinia virus include, but are not limited to, Copenhagen, Western Reserve, Wyeth, Lister, EM63, ACAM2000, CV-1, modified vaccinia Ankara (MVA), Dairen I, GLV-1h68, IHD-J, L-IVP, LC16m8, LC16mO, Tashkent, Tian Tan, and WAU86/88-1.

Thymidine Kinase Mutants

Several current clinical studies testing vaccinia virus as an oncolytic virus harbor deletions in the viral Thymidine Kinase (TK) gene. This deletion attenuates the virus, rendering the virus dependent upon the activity of cellular thymidine kinase for DNA replication and, thus, viral propagation. Cellular thymidine kinase is expressed at a low level in most normal tissues and at elevated levels in many cancer cells. Through metabolic targeting, TK-viruses can grow in cells that have a high metabolic rate (e.g., healthy cells or tumor cells) and will not grow well in cells that have low levels of thymidine kinase. Since there exist quiescent tumour cells (e.g., cancer stem cells), TK-viruses are likely compromised in their ability to kill this population of cancer cells just as chemotherapy is largely ineffective. The modified viral vectors described in this disclosure retains virus synthetic machinery (including TK) and may propagate in quiescent cancer cells. The viral modifications of this disclosure may allow the virus to be highly selective without deleting TK or other DNA metabolizing enzymes (e.g., ribonucleotide reductase) and could be more effective in tumors with a low metabolic rate.

Virus Propagation

The present invention features poxviruses, including those constructed with one or more gene deletions compared to wild-type, such that the virus exhibits desirable properties for use against cancer cells, while being less toxic or non-toxic to non-cancer cells. This section summarizes various protocols, by way of example, for producing recombinant poxviruses described herein, such as methods for generating mutated viruses through the use of recombinant DNA technology.

For example, to generate mutations in the poxvirus genome, native and modified polypeptides may be encoded by a nucleic acid molecule comprised in a vector. Vectors include plasmids, cosmids, viruses (bacteriophage, animal viruses, and plant viruses), and artificial chromosomes (e.g., YACs). One of skill in the art would be well equipped to construct a vector through standard recombinant techniques, which are described in Sambrook et al., (1989) and Ausubel et al., 1994, both incorporated herein by reference. In addition to encoding a modified polypeptide such as modified gelonin, a vector may encode non-modified polypeptide, sequences such as a tag or targeting molecule.

In order to propagate a vector in a host cell, it may contain one or more origins of replication sites (often termed “ori”), which is a specific nucleic acid sequence at which replication is initiated. Alternatively an autonomously replicating sequence (ARS) can be employed if the host cell is yeast.

In the context of expressing a heterologous nucleic acid sequence, “host cell” refers to a prokaryotic or eukaryotic cell, and it includes any transformable organisms that is capable of replicating a vector and/or expressing a heterologous gene encoded by a vector. A host cell can, and has been, used as a recipient for vectors or viruses (which does not qualify as a vector if it expresses no exogenous polypeptides). A host cell may be “transfected” or “transformed,” which refers to a process by which exogenous nucleic acid, such as a modified protein-encoding sequence, is transferred or introduced into the host cell. A transformed cell includes the primary subject cell and its progeny. Host cells may be derived from prokaryotes or eukaryotes, including yeast cells, insect cells, and mammalian cells, depending upon whether the desired result is replication of the vector or expression of part or all of the vector-encoded nucleic acid sequences. Numerous cell lines and cultures are available for use as a host cell, and they can be obtained through the American Type Culture Collection (ATCC), which is an organization that serves as an archive for living cultures and genetic materials (www.atcc.org). An appropriate host can be determined by one of skill in the art based on the vector backbone and the desired result. A plasmid or cosmid, for example, can be introduced into a prokaryote host cell for replication of many vectors. Bacterial cells used as host cells for vector replication and/or expression include DH5α, JM109, and KCB, as well as a number of commercially available bacterial hosts such as SURE® Competent Cells and SOLOPACK™ Gold Cells (STRATAGENE®, La Jolla, Calif.). Alternatively, bacterial cells such as E. coli LE392 could be used as host cells for phage viruses. Appropriate yeast cells include Saccharomyces cerevisiae, Saccharomyces pombe, and Pichia pastoris. Examples of eukaryotic host cells for replication and/or expression of a vector include HeLa, NIH3T3, Jurkat, 293, Cos, CHO, Saos, and PC12. Many host cells from various cell types and organisms are available and would be known to one of skill in the art. Similarly, a viral vector may be used in conjunction with either a eukaryotic or prokaryotic host cell, particularly one that is permissive for replication or expression of the vector. Some vectors may employ control sequences that allow it to be replicated and/or expressed in both prokaryotic and eukaryotic cells. One of skill in the art would further understand the conditions under which to incubate all of the above described host cells to maintain them and to permit replication of a vector. Also understood and known are techniques and conditions that would allow large-scale production of vectors, as well as production of the nucleic acids encoded by vectors and their cognate polypeptides, proteins, or peptides.

Genetic Modifications to the Orthopoxvirus Genome Methods of Genetic Modification

Methods for the insertion or deletion of nucleic acids from a target genome include those described herein and known in the art. One such method that can be used for incorporating polynucleotides encoding target genes into a target genome involves the use of transposons. Transposons are polynucleotides that encode transposase enzymes and contain a polynucleotide sequence or gene of interest flanked by 5′ and 3′ excision sites. Once a transposon has been delivered to a target nucleic acid (e.g., in a host cell), expression of the transposase gene commences and results in active enzymes that cleave the gene of interest from the transposon. This activity is mediated by the site-specific recognition of transposon excision sites by the transposase. In certain cases, these excision sites may be terminal repeats or inverted terminal repeats. Once excised from the transposon, the gene of interest can be integrated into the target genome by transposase-catalyzed cleavage of similar excision sites that exist within the nuclear genome of the cell. This allows the gene of interest to be inserted into the cleaved nuclear DNA at the complementary excision sites, and subsequent covalent ligation of the phosphodiester bonds that join the gene of interest to the DNA of the target genome completes the incorporation process. In certain cases, the transposon may be a retrotransposon, such that the gene encoding the target gene is first transcribed to an RNA product and then reverse-transcribed to DNA before incorporation in the mammalian cell genome. Transposon systems include the piggybac transposon (described in detail in, e.g., WO 2010/085699) and the sleeping beauty transposon (described in detail in, e.g., US2005/0112764), the disclosures of each of which are incorporated herein by reference.

Additional methods for nucleic acid delivery to effect expression of compositions of the present invention are believed to include virtually any method by which a nucleic acid (e.g., DNA, including viral and non-viral vectors) can be introduced into an organelle, a cell, a tissue or an organism, as described herein or as would be known to one of ordinary skill in the art. Such methods include, but are not limited to, direct delivery of DNA such as by injection (U.S. Pat. Nos. 5,994,624, 5,981,274, 5,945,100, 5,780,448, 5,736,524, 5,702,932, 5,656,610, 5,589,466 and 5,580,859, each incorporated herein by reference), including microinjection (Harland and Weintraub, 1985; U.S. Pat. No. 5,789,215, incorporated herein by reference); by electroporation (U.S. Pat. No. 5,384,253, incorporated herein by reference); by calcium phosphate precipitation (Graham and Van Der Eb, 1973; Chen and Okayama, 1987; Rippe et al., 1990); by using DEAE-dextran followed by polyethylene glycol (Gopal, 1985); by direct sonic loading (Fechheimer et al., 1987); by liposome mediated transfection (Nicolau and Sene, 1982; Fraley et al., 1979; Nicolau et al., 1987; Wong et al., 1980; Kaneda et al., 1989; Kato et al., 1991); by microprojectile bombardment (PCT Application Nos. WO 94/09699 and 95/06128; U.S. Pat. Nos. 5,610,042; 5,322,783, 5,563,055, 5,550,318, 5,538,877 and 5,538,880, and each incorporated herein by reference); by agitation with silicon carbide fibers (Kaeppler et al., 1990; U.S. Pat. Nos. 5,302,523 and 5,464,765, each incorporated herein by reference); by Agrobacterium-mediated transformation (U.S. Pat. Nos. 5,591,616 and 5,563,055, each incorporated herein by reference); or by PEG-mediated transformation of protoplasts (Omirulleh et al., 1993; U.S. Pat. Nos. 4,684,611 and 4,952,500, each incorporated herein by reference); by desiccation/inhibition-mediated DNA uptake (Potrykus et al., 1985). Through the application of techniques such as these, organelle(s), cell(s), tissue(s) or organism(s) may be stably or transiently transformed.

CopMD5p, CopMD3p, and CopMD5p3p Deletions.

In various embodiments, various genes are deleted to enhance the oncolytic activity of the orthopoxvirus. Most of the deletions described herein are either involved in blocking a host response to viral infection or otherwise have an unknown function. In various embodiments, at least one of the genes depicted in Table 2 are deleted from the recombinant orthopoxvirus genome. In various embodiments, at least 2, 3, 4, 5, 6, 7, 8, 9, 10, 11, 12, 13, 14, 15, 16, 17, 18, 19, 20, 21, 22, 23, 24, 25, 26, 27, 28, 29, 30 or 31 of the genes depicted in Table 2 are deleted from the recombinant orthopox genome. In various embodiments, all of the genes depicted in Table 2 are deleted from the recombinant orthopoxvirus genome. Three exemplary embodiments of the present invention, CopMD5p, CopMD3p and CopMD5p3p, are described herein. Depicted in Table 2 below are clusters of deleted genes and their function in CopMD5p, CopMD3p, and CopMD5p3p virus. In various embodiments, where two copies of an ITR exist, only the right ITR of the genome is deleted and the left ITR remains intact. Deletions are confirmed by whole genome sequencing.

TABLE 2 Deleted genes in Orthopoxviruses Name Category Function Virus Deletions C2L Host interaction Inhibits NFkB CopMD5p CopMD5p3p C1L Unknown Unknown N1L Host interaction Inhibits NFkB and Apoptosis N2L Host interaction Inhibits IRF3 M1L Unknown Unknown M2L Host interaction Inhibits NFkB and Apoptosis K1L Host interaction Inhibits PICR and NF-kB K2L Host interaction Prevents cell fusion K3L Host interaction Inhibits PKR K4L DNA replication DNA modifying nuclease K5L Pseudogene Pseudogene K6L Pseudogene Pseudogene K7R Host interaction Inhibits NFkB and IRF3 F1L Host interaction Inhibits Apoptosis F2L DNA replication Deoxyuridine triphosphatase F3L Host interaction Virulence factor Bl4R Pseudogene Pseudogene CopMD3p Bl5R Unknovvn Unknown Bl6R Host interaction IL-1-beta-inhibitor B17L Unknown Unknown B18R Unknown Ankyrin-like B19R Host interaction Secreted IFNa sequestor B20R Unknown Ankyrin-like B21R-ITR* Unknown Unknown B22R-ITR* Unknown Unknown B23R-ITR* Unknown Unknown B24R-ITR* Unknown Unknown B25R-ITR* Unknown Unknown B26R-ITR* Unknown Unknown B27R-ITR* Unknown Unknown B28R-ITR* Pseudogene TNF-a receptor B29R-ITR* Host interaction Secreted CC-chemokine sequestor

B8R Gene Deletions.

In various embodiments, the orthopox viruses are further genetically modified to contain deletions in the B8R gene. The vaccinia virus B8R gene encodes a secreted protein with homology to gamma interferon receptor (IFN-7). In vitro, the B8R protein binds to and neutralizes the antiviral activity of several species of gamma inteterferon including human and rat gamma interferon; it does not, however, bind significantly to murine IFN-7. Deleting the B8R gene prevents the impairment of IFN-γ in humans. Deletion of the B8R gene results in enhanced safety without a concomitant reduction in immunogenicity.

Transgene Insertions

In various embodiments, additional transgenes may be inserted into the vector. In various embodiments, one, two or three transgenes are inserted into the locus of the deleted B8R gene. In some strains, in addition to the transgene(s) present at the site of the B8R deletion, the strain also has, at least one transgene is inserted into an additional locus on the orthopox virus that is not the locus of the deleted B8R gene. In various embodiments, at least one transgene is inserted into boundaries of the 5p deletions, at least one transgene is inserted into the boundaries of the 3p deletions or both. In various, embodiments at least three, four, five or more transgenes are inserted into the modified orthopox virus genome.

In various embodiments, the recombinant orthopoxvirus vector can include at least one transgene encoding an immune checkpoint inhibitor. Exemplary immune checkpoint inhibitors for expression by the orthopoxvirus of the compositions and methods of the invention include but are not limited to OX40 ligand, ICOS ligand, anti-CD47 antibody or antigen-binding fragment thereof, anti-CD40/CD40L antibody or antigen-binding fragment thereof, anti-Lag3 antibody or antigen-binding fragment thereof, anti-CTLA-4 antibody or antigen-binding fragment thereof, anti-PD-L1 antibody or antigen-binding fragment thereof, anti-PD1 antibody or antigen-binding fragment thereof, and anti-Tim-3 antibody or antigen-binding fragment thereof.

In various embodiments, the recombinant orthopoxvirus vector can include at least one transgene encoding encoding at least one interleukin protein. Exemplary interleukin proteins for expression by the orthopoxvirus of the compositions and methods of the invention include but are not limited to IL-1 alpha, IL-1 beta, IL-2, IL-4, IL-7, IL-10, IL-12 p35, IL-12 p40, IL-12 p70, IL-15, IL-18, IL-21, and IL-23.

In various embodiments, recombinant orthopoxvirus vector can include a transgene encoding an interferon. Exemplary interferons for expression by the orthopoxvirus of the compositions and methods of the invention include but are not limited to IFN-alpha, IFN-beta, IFN-delta, IFN-epsilon, IFN-tau, IFN-omega, IFN-zeta, and IFN-gamma.

In various embodiments, the recombinant orthopoxvirus vector can include a transgene encoding a TNF superfamily member protein. Exemplary TNF superfamily member proteins for expression by the orthopoxvirus of the compositions and methods of the invention include but are not limited to TRAIL, Fas ligand, LIGHT (TNFSF-14), TNF-alpha, and 4-1BB ligand.

In various embodiments, the recombinant orthopoxvirus vector can include a transgene encoding a cytokine. Exemplary cytokines for expression by the orthopoxvirus of the compositions and methods of the invention include but are not limited to GM-CSF, Flt3 ligand, CD40 ligand, anti-TGF-beta, anti-VEGF-R2, and cGAS (guanyl adenylate cyclase).

In various embodiments, the recombinant orthopoxvirus vector can include a transgene encoding a tumor-associated antigen. Exemplary tumor-associated antigens for expression by the orthopoxvirus of the compositions and methods of the invention include but are not limited to CD19, CD33, EpCAM, CEA, PSMA, EGFRvIII, CD133, EGFR, CDH19, ENPP3, DLL3, MSLN, ROR1, HER2, HLAA2, EpHA2, EpHA3, MCSP, CSPG4, NG2, RON, FLT3, BCMA, CD20, FAPα, FRα, CA-9, PDGFRα, PDGFRβ, FSP1, S100A4, ADAM12m, RET, MET, FGFR, INSR, NTRK, MAGE-A3, NY-ESO-1, one or more human papillomavirus (HPV) proteins, E6 and E7 proteins of HPV16, E6 and E7 proteins of HPV18, brachyury, or prostatic acid phosphatase, or one or more fragments thereof. Additional examples of tumor-associated antigens for use in conjunction with the compositions and methods described herein include, but are not limited to, those listed in tables 3-30.

Methods of Treatment Pharmaceutical Composition, Administration, and Doses

Therapeutic compositions containing recombinant orthopoxvirus vectors of the invention can be prepared using methods known in the art. For example, such compositions can be prepared using, e.g., physiologically acceptable carriers, excipients or stabilizers (Remington's Pharmaceutical Sciences 16th edition, Osol, A. Ed. (1980); incorporated herein by reference), and in a desired form, e.g., in the form of lyophilized formulations or aqueous solutions.

To induce oncolysis, kill cells, inhibit growth, inhibit metastases, decrease tumor size and otherwise reverse or reduce the malignant phenotype of tumor cells, using the methods and compositions of the present invention, one may contact a tumor with the modified orthopoxvirus, e.g., by administration of the orthopoxvirus to a patient having cancer by way of, for instance, one or more of the routes of administration described herein. The route of administration may vary with the location and nature of the cancer, and may include, e.g., intradermal, transdermal, parenteral, intravenous, intramuscular, intranasal, subcutaneous, regional (e.g., in the proximity of a tumor, particularly with the vasculature or adjacent vasculature of a tumor), percutaneous, intratracheal, intraperitoneal, intraarterial, intravesical, intratumoral, inhalation, perfusion, lavage, and oral administration and formulation.

The term “intravascular” is understood to refer to delivery into the vasculature of a patient, meaning into, within, or in a vessel or vessels of the patient. In certain embodiments, the administration is into a vessel considered to be a vein (intravenous), while in others administration is into a vessel considered to be an artery. Veins include, but are not limited to, the internal jugular vein, a peripheral vein, a coronary vein, a hepatic vein, the portal vein, great saphenous vein, the pulmonary vein, superior vena cava, inferior vena cava, a gastric vein, a splenic vein, inferior mesenteric vein, superior mesenteric vein, cephalic vein, and/or femoral vein. Arteries include, but are not limited to, coronary artery, pulmonary artery, brachial artery, internal carotid artery, aortic arch, femoral artery, peripheral artery, and/or ciliary artery. It is contemplated that delivery may be through or to an arteriole or capillary.

Intratumoral injection, or injection directly into the tumor vasculature is specifically contemplated for discrete, solid, accessible tumors. Local, regional or systemic administration also may be appropriate. The viral particles may advantageously be contacted by administering multiple injections to the tumor, spaced, for example, at approximately 1 cm intervals. In the case of surgical intervention, the present invention may be used preoperatively, such as to render an inoperable tumor subject to resection. Continuous administration also may be applied where appropriate, for example, by implanting a catheter into a tumor or into tumor vasculature. Such continuous perfusion may take place, for example, for a period of from about 1-2 hours, to about 2-6 hours, to about 6-12 hours, or about 12-24 hours following the initiation of treatment. Generally, the dose of the therapeutic composition via continuous perfusion may be equivalent to that given by a single or multiple injections, adjusted over a period of time during which the perfusion occurs. It is further contemplated that limb perfusion may be used to administer therapeutic compositions of the present invention, particularly in the treatment of melanomas and sarcomas.

Treatment regimens may vary, and often depend on tumor type, tumor location, disease progression, and health and age of the patient. Certain types of tumor will require more aggressive treatment, while at the same time, certain patients cannot tolerate more taxing protocols. The clinician will be best suited to make such decisions based on the known efficacy and toxicity (if any) of the therapeutic formulations. In certain embodiments, the tumor being treated may not, at least initially, be resectable. Treatments with the therapeutic agent of the disclosure may increase the resectability of the tumor due to shrinkage at the margins or by elimination of certain particularly invasive portions. Following treatments, resection may be possible. Additional treatments subsequent to resection will serve to eliminate microscopic residual disease at the tumor site.

The treatments may include various “unit doses.” Unit dose is defined as containing a predetermined-quantity of the therapeutic composition. The quantity to be administered, and the particular route and formulation, are within the skill of those in the clinical arts. A unit dose need not be administered as a single injection but may comprise continuous infusion over a set period of time. Unit dose of the present invention may conveniently be described in terms of plaque forming units (pfu) for a viral construct. Unit doses may range from 10³, 10⁴, 10⁵, 10⁶, 10⁷, 10⁸, 10⁹, 10¹⁰, 10¹¹, 10¹², to 10¹³ pfu and higher. Additionally or alternatively, depending on the kind of virus and the titer attainable, one may deliver 1 to 100, 10 to 50, 100-1000, or up to about or at least about 1×10⁴, 1×10⁵, 1×10⁶, 1×10⁷, 1×10⁸, 1×10⁹, 1×10¹⁰, 1×10¹¹, 1×10¹², 1×10¹³, 1×10¹⁴, or 1×10¹⁵ or higher infectious viral particles (vp), including all values and ranges there between, to the tumor or tumor site.

Another method of delivery of the recombinant orthopoxvirus genome disclosed herein to cancer or tumor cells may be via intratumoral injection. However, the pharmaceutical compositions disclosed herein may alternatively be administered parenterally, intravenously, intradermally, intramuscularly, transdennally or even intraperitoneally as described in U.S. Pat. Nos. 5,543,158; 5,641,515 and 5,399,363 (each specifically incorporated herein by reference in its entirety). Injection of nucleic acid constructs may be delivered by syringe or any other method used for injection of a solution, as long as the expression construct can pass through the particular gauge of needle required for injection. An exemplary needleless injection system that may be used for the administration of recombinant orthopoxviruses described herein is exemplified in U.S. Pat. No. 5,846,233. This system features a nozzle defining an ampule chamber for holding the solution and an energy device for pushing the solution out of the nozzle to the site of delivery. Another exemplary syringe system is one that permits multiple injections of predetermined quantities of a solution precisely at any depth (U.S. Pat. No. 5,846,225).

Mixtures of the viral particles or nucleic acids described herein may be prepared in water suitably mixed with one or more excipients, carriers, or diluents. Dispersions may also be prepared in glycerol, liquid polyethylene glycols, and mixtures thereof and in oils. Under ordinary conditions of storage and use, these preparations may contain a preservative to prevent the growth of microorganisms. The pharmaceutical forms suitable for injectable use include sterile aqueous solutions or dispersions and sterile powders for the extemporaneous preparation of sterile injectable solutions or dispersions (U.S. Pat. No. 5,466,468, specifically incorporated herein by reference in its entirety). In all cases the form may be sterile and may be fluid to the extent that easy syringability exists. It may be stable under the conditions of manufacture and storage and must be preserved against the contaminating action of microorganisms, such as bacteria and fungi. The carrier can be a solvent or dispersion medium containing, for example, water, ethanol, polyol (e.g., glycerol, propylene glycol, and liquid polyethylene glycol, and the like), suitable mixtures thereof, and/or vegetable oils. Proper fluidity may be maintained, for example, by the use of a coating, such as lecithin, by the maintenance of the required particle size in the case of dispersion and by the use of surfactants. The prevention of the action of microorganisms can be brought about by various antibacterial and antifungal agents, for example, parabens, chlorobutanol, phenol, sorbic acid, thimerosal, and the like. In many cases, it will be preferable to include isotonic agents, for example, sugars or sodium chloride. Prolonged absorption of the injectable compositions can be brought about by the use in the compositions of agents delaying absorption, for example, aluminum monostearate and gelatin.

For parenteral administration in an aqueous solution, for example, the solution may be suitably buffered if necessary and the liquid diluent first rendered isotonic with sufficient saline or glucose. These particular aqueous solutions are especially suitable for intravenous, intramuscular, subcutaneous, intratumoral and intraperitoneal administration. In this connection, sterile aqueous media that can be employed will be known to those of skill in the art in light of the present disclosure. For example, one dosage may be dissolved in 1 ml of isotonic NaCl solution and either added to 1000 ml of hypodermoclysis fluid or injected at the proposed site of infusion. Some variation in dosage will necessarily occur depending on the condition of the subject being treated. The person responsible for administration will, in any event, determine the appropriate dose for the individual subject. Moreover, for human administration, preparations should meet sterility, pyrogenicity, general safety, and purity standards as required by FDA Office of Biologics standards.

As used herein, “carrier” includes any and all solvents, dispersion media, vehicles, coatings, diluents, antibacterial and antifungal agents, isotonic and absorption delaying agents, buffers, carrier solutions, suspensions, colloids, and the like. The use of such media and agents for pharmaceutical active substances is well known in the art. Except insofar as any conventional media or agent is incompatible with the active ingredient, its use in the therapeutic compositions is contemplated. Supplementary active ingredients can also be incorporated into the compositions. The phrase “pharmaceutically acceptable” or “pharmacologically-acceptable” refers to molecular entities and compositions that do not produce an allergic or similar untoward reaction when administered to a human. The preparation of an aqueous composition that contains a protein as an active ingredient is well understood in the art. Typically, such compositions are prepared as injectables, either as liquid solutions or suspensions; solid forms suitable for solution in, or suspension in, liquid prior to injection can also be prepared.

Cancer

The recombinant orthopoxvirus disclosed herein can be administered to a mammalian subject, such as a human, suffering from a cell proliferation disorder, such as cancer, e.g., to kill cancer cells directly by oncolysis and/or to enhance the effectiveness of the adaptive immune response against the target cancer cells. In some embodiments, the cell proliferation disorder is a cancer, such as leukemia, lymphoma, liver cancer, bone cancer, lung cancer, brain cancer, bladder cancer, gastrointestinal cancer, breast cancer, cardiac cancer, cervical cancer, uterine cancer, head and neck cancer, gallbladder cancer, laryngeal cancer, lip and oral cavity cancer, ocular cancer, melanoma, pancreatic cancer, prostate cancer, colorectal cancer, testicular cancer, or throat cancer. In particular cases, the cell proliferation disorder may be a cancer selected from the group consisting of acute lymphoblastic leukemia (ALL), acute myeloid leukemia (AML), chronic lymphocytic leukemia (CLL), chronic myelogenous leukemia (CML), adrenocortical carcinoma, AIDS-related lymphoma, primary CNS lymphoma, anal cancer, appendix cancer, astrocytoma, atypical teratoid/rhabdoid tumor, basal cell carcinoma, bile duct cancer, extrahepatic cancer, ewing sarcoma family, osteosarcoma and malignant fibrous histiocytoma, central nervous system embryonal tumors, central nervous system germ cell tumors, craniopharyngioma, ependymoma, bronchial tumors, burkitt lymphoma, carcinoid tumor, primary lymphoma, chordoma, chronic myeloproliferative neoplasms, colon cancer, extrahepatic bile duct cancer, ductal carcinoma in situ (DCIS), endometrial cancer, ependymoma, esophageal cancer, esthesioneuroblastoma, extracranial germ cell tumor, extragonadal germ cell tumor, fallopian tube cancer, fibrous histiocytoma of bone, gastrointestinal carcinoid tumor, gastrointestinal stromal tumors (GIST), testicular germ cell tumor, gestational trophoblastic disease, glioma, childhood brain stem glioma, hairy cell leukemia, hepatocellular cancer, langerhans cell histiocytosis, hodgkin lymphoma, hypopharyngeal cancer, islet cell tumors, pancreatic neuroendocrine tumors, wilms tumor and other childhood kidney tumors, langerhans cell histiocytosis, small cell lung cancer, cutaneous T-cell lymphoma, intraocular melanoma, merkel cell carcinoma, mesothelioma, metastatic squamous neck cancer, midline tract carcinoma, multiple endocrine neoplasia syndromes, multiple myeloma/plasma cell neoplasm, myelodysplastic syndromes, nasal cavity and paranasal sinus cancer, nasopharyngeal cancer, neuroblastoma, non-hodgkin lymphoma (NHL), non-small cell lung cancer (NSCLC), epithelial ovarian cancer, germ cell ovarian cancer, low malignant potential ovarian cancer, pancreatic neuroendocrine tumors, papillomatosis, paraganglioma, paranasal sinus and nasal cavity cancer, parathyroid cancer, penile cancer, pharyngeal cancer, pheochromocytoma, pituitary tumor, pleuropulmonary blastoma, primary peritoneal cancer, rectal cancer, retinoblastoma, rhabdomyosarcoma, salivary gland cancer, kaposi sarcoma, rhabdomyosarcoma, sézary syndrome, small intestine cancer, soft tissue sarcoma, throat cancer, thymoma and thymic carcinoma, thyroid cancer, transitional cell cancer of the renal pelvis and ureter, urethral cancer, endometrial uterine cancer, uterine sarcoma, vaginal cancer, vulvar cancer, and Waldenström macroglobulinemia.

A physician having ordinary skill in the art can readily determine an effective amount of the recombinant orthopoxvirus vector for administration to a mammalian subject (e.g., a human) in need thereof. For example, a physician may start prescribing doses of recombinant orthopoxvirus vector at levels lower than that required in order to achieve the desired therapeutic effect and gradually increase the dosage until the desired effect is achieved. Alternatively, a physician may begin a treatment regimen by administering a dose of recombinant orthopoxvirus vector and subsequently administer progressively lower doses until a therapeutic effect is achieved (e.g., a reduction in the volume of one or more tumors). In general, a suitable daily dose of a recombinant orthopoxvirus vector of the invention will be an amount of the recombinant orthopoxvirus vector which is the lowest dose effective to produce a therapeutic effect. A daily dose of a therapeutic composition of the recombinant orthopoxvirus vector of the invention may be administered as a single dose or as two, three, four, five, six or more doses administered separately at appropriate intervals throughout the day, week, month, or year, optionally, in unit dosage forms. While it is possible for the recombinant orthopoxvirus vector of the invention to be administered alone, it may also be administered as a pharmaceutical formulation in combination with excipients, carriers, and optionally, additional therapeutic agents.

Recombinant orthopoxvirus vectors of the invention can be monitored for their ability to attenuate the progression of a cell proliferation disease, such as cancer, by any of a variety of methods known in the art. For instance, a physician may monitor the response of a mammalian subject (e.g., a human) to treatment with recombinant orthopoxvirus vector of the invention by analyzing the volume of one or more tumors in the patient. Alternatively, a physician may monitor the responsiveness of a subject (e.g., a human) t to treatment with recombinant orthopoxvirus vector of the invention by analyzing the T-reg cell population in the lymph of a particular subject. For instance, a physician may withdraw a sample from a mammalian subject (e.g., a human) and determine the quantity or density of cancer cells using established procedures, such as fluorescence activated cell sorting. A finding that the quantity of cancer cells in the sample has decreased (e.g., by 1%, 2%, 3%, 4%, 5%, 6%, 7%, 8%, 9%, 10%, 20%, 30%, 40%, 50%, 60%, 70%, 80%, 90%, 95%, 96%, 97%, 98%, 99%, or more) relative to the quantity of cancer cells in a sample obtained from the subject prior to administration of the recombinant orthopoxvirus may be an indication that the orthopoxvirus administration is effectively treating the cancer.

Combination Therapy

In various embodiments, the recombinant orthopoxvirus may be co-administered with other cancer therapeutics. Furthermore, in various embodiments, the recombinant orthopoxviruses described herein are administered in conjunction with other cancer treatment therapies, e.g., radiotherapy, chemotherapy, surgery, and/or immunotherapy. In some aspects of this invention, the recombinant orthopoxvirus described herein are administered in conjunction with checkpoint inhibitors. In various embodiments, the recombinant orthopoxvirus may be administered in conjunction with treatment with another immunoncology product. The recombinant orthopoxviruses of the present invention and other therapies or therapeutic agents can be administered simultaneously or sequentially by the same or different routes of administration. The determination of the identity and amount of therapeutic agent(s) for use in the methods of the present invention can be readily made by ordinarily skilled medical practitioners using standard techniques known in the art.

The recombinant orthopoxvirus vectors described herein may be administered with one or more additional agents, such as an immune checkpoint inhibitor. For instance, the recombinant orthopoxvirus vector can be administered simultaneously with, admixed with, or administered separately from an immune checkpoint inhibitor. Exemplary immune checkpoint inhibitors for use in conjunction with the compositions and methods of the invention include but are not limited to OX40 ligand, ICOS ligand, anti-CD47 antibody or antigen-binding fragment thereof, anti-CD40/CD40L antibody or antigen-binding fragment thereof, anti-Lag3 antibody or antigen-binding fragment thereof, anti-CTLA-4 antibody or antigen-binding fragment thereof, anti-PD-L1 antibody or antigen-binding fragment thereof, anti-PD1 antibody or antigen-binding fragment thereof, and anti-Tim-3 antibody or antigen-binding fragment thereof.

Additionally or alternatively, a vector of the invention can be administered simultaneously with, admixed with, or administered separately from an interleukin (IL). For instance, the recombinant orthopoxvirus vector can be administered simultaneously with, admixed with, or administered separately from an interleukin. Exemplary interleukins for use in conjunction with the compositions and methods of the invention include but are not limited to IL-1 alpha, IL-1 beta, IL-2, IL-4, IL-7, IL-10, IL-12 p35, IL-12 p40, IL-12 p70, IL-15, IL-18, IL-21, and IL-23.

Additionally or alternatively, a vector of the invention can be administered simultaneously with, admixed with, or administered separately from an interferon. For instance, the recombinant orthopoxvirus vector can be administered simultaneously with, admixed with, or administered separately from an interferon. Exemplary interferons for use in conjunction with the compositions and methods of the invention include but are not limited to IFN-alpha, IFN-beta, IFN-delta, IFN-epsilon, IFN-tau, IFN-omega, IFN-zeta, and IFN-gamma.

Additionally or alternatively, a vector of the invention can be administered simultaneously with, admixed with, or administered separately from a TNF superfamily member protein. For instance, the recombinant orthopoxvirus vector can be administered simultaneously with, admixed with, or administered separately from a TNF superfamily member protein. Exemplary TNF superfamily member proteins for use in conjunction with the compositions and methods of the invention include but are not limited to TRAIL, Fas ligand, LIGHT (TNFSF-14), TNF-alpha, and 4-1BB ligand.

Additionally or alternatively, a vector of the invention can be administered simultaneously with, admixed with, or administered separately from a cytokine. For instance, the recombinant orthopoxvirus vector can be administered simultaneously with, admixed with, or administered separately from a cytokine. Exemplary cytokines for use in conjunction with the compositions and methods of the invention includes but are not limited to GM-CSF, Flt3 ligand, CD40 ligand, anti-TGF-beta, anti-VEGF-R2, and cGAS (guanyl adenylate cyclase).

TABLE 3  Ovarian cancer Tumor-associated Reported immunogenic No. antigen epitopes Sources 1 Kallikrein 4 FLGYLILGV(SEQ ID NO: Wilkinson et al. Cancer Immunol. 210); Immunother. 61(2):169-79 (2012). SVSESDTIRSISIAS SEQ Hural et al. J. Immunol. 169(1):557- ID NO: 211; 65 (2002). LLANGRMPTVLQCVN (SEQ ID NO: 212); and RMPTVLQCVNVSVVS (SEQ ID NO: 213) 2 PBF CTACRW1CKACQR(SEQ Tsukahara et al. Cancer Res. ID NO: 214) 64(15):5442-8 (2004). 3 PRAME VLDGLDVLL SEQ ID Kessler et al. J. Exp. Med. NO: 215); 193(1):73-88 (2001). SLYSFPEPEA(SEQ ID Ikeda et al. Immunity 6(2):199-208 NO: 216); (1997). ALYVDSLFFL (SEQ ID NO: 217); SLLQHLIGL(SEQ ID NO: 218); and LYVDSLFFL (SEQ ID NO: 219) 4 WTI TSEKRPFMCAY (SEQ ID Asemissen et al. Clin. Cancer Res. NO: 220); CMTWNQMNL 12(24):7476-82 (2006) (SEQ ID NO: 221); Ohminami et al. Blood. 95(1):286- LSHLQMHSRICH (SEQ ID 93 (2000). NO: 222); Guo et al. Blood. 106(4):1415-8 KRYFKLSHLQMHSRICH 2005). (SEQ ID NO: 223); and Lin et al. J. Immunother. 36(3):159- KRYFKLSHLQMHSRKH 70 (2013). (SEQ ID NO: 223) Fujiki et al. J. Immunother. 30(3):282-93 (2007). 5 HSDLI CYMEAVAL (SEQ ID NO: Wick et al. Clin. Cancer Res. 224) 20(5):1125-34 (2014). 6 Mesothelin SLLFLLFSL (SEQ ID NO: Hassan et al. Appl. 225) Immunohistochem. Mol. Morphol. VLPLTVAEV (SEQ ID 13(3):243-7 (2005). NO: 226) Thomas et al J Exp Med. 2004 Aug ALQGGGPPY (SEQ ID 2; 200(3): 297-306. NO: 227) LYPKARLAF (SEQ ID NO: 228) AFLPWHRLF (SEQ ID NO: 229) 7 NY-ESO-1 HLA-A2-restricted peptide Jager et al. Proc. Natl. Acad. Scie. p157-165 (SLLMWITQC U.S.A. 103(39):14453-8 (2006). SEQ ID NO: 230)), HLA- Gnjatic et al. PNAS Cw3-restricted p92-100 September 26,2000 vol. 97 no. 20 p. (LAMP-FATPM (SEQ ID 10919 NO: 231)) and HLA-Cw6- Jager et al. J Exp Med. 187(2):265- restricted p80-88 70 (1998). (ARGPESRLL (SEQ ID  Chen et al. J Immunol. 165(2):948- NO: 232)) 55 (2000). SLLMWITQC SEQ ID Valmori et al. Cancer Res. NO: 230) 60(16):4499-506 (2000). MLMAQEALAFL (SEQ ID Aamoudse et al. Int J Cancer. NO: 233) 82(3):442-8 (1999). YLAMPFATPME (SEQ ID Eikawa et al. Int J Cancer. NO: 234) 132(2):345-54 (2013). ASGPGGGAPR (SEQ ID Wang et al. J Immunol. 161(7):3598- NO: 235) 606 (1998). LAAQERRVPR (SEQ ID Matsuzald et al. Cancer Immunol NO: 236) Immunother. 57(8)1185-95 (2008). TVSGNILITR (SEQ ID Ebert et al. Cancer Res. 69(3):1046- NO: 237) 54 (2009). APRGPHGGAASGL (SEQ Eikawa et al. Int J Cancer. ID NO: 238) 132(2):345-54 (2013). MPFATPMEAEL (SEQ ID Knights et al. Cancer Immunol NO: 239) Immunother. 58(3):325-38 (2009). KEFTVSGNILTI (SEQ ID Jager et al. Cancer Immun. 2:12 NO: 240) (2002). MPFATPMEA (SEQ ID Zeng et al. Proc Natl Acad Sci U S NO: 241) A. 98(7):3964-9 (2001). FATPMEAEL (SEQ ID Mandic et al. J Immunol. NO: 242) 174(3):1751-9 (2005). FATPMEAELAR (SEQ ID  Chen et al. Proc Natl Acad Sci U S NO: 243) A. 101(25):9363-8 (2004). LAMPFATPM (SEQ ID Ayyoub et al. Clin Cancer Res. NO: 231) 16(18):4607-15 (2010). ARGPESRLL (SEQ ID NO: Slager et al. J Immunol. 232) 172(8):5095-102 (2004). SLLMWITQCFLPVF (SEQ  Mizote et at. Vaccine. 28(32):5338- ID NO: 244) 46 (2010). LLEFYLAMPFATPMEAE Jager et al. J Exp Med. 191(4):625- L-ARRSLAQ SEQ ID NO:  30 (2000). 245) Zarour et al. Cancer Res. EFYLAMPFATPM(SEQ  60(17):4946-52 (2000). ID NO: 246) Zeng et at. J Immunol. 165(2):1153- PGVLIKEFTVSGNILTIR 9(2000). L-TAADHR (SEQ ID NO: Bioley et al. Clin Cancer Res. 247) 15(13):4467-74 (2009). RLLEFYLAMPFA (SEQ Zarour et al. Cancer Res. 62(1):213- ID NO: 248) 8 (2002). QGAMLAAQERRVPRAA Hasegawa et al. Clin Cancer Res. E-VPR(SEQ ID NO: 249) 12(6):1921-7 (2006). PFATPMEAELARR (SEQ ID NO: 250) PGVLLKEFTVSGNILTIR LT (SEQ ID NO: 251) VLLKEFTVSG (SEQ ID NO: 252) AADHRQLQLSISSCLQQ (SEQ ID NO: 253) LKEFTVSGNILTIRL (SEQ ID NO: 254) PGVLLKEFTVSGNILTIR L-TAADHR (SEQ ID NO: 247) LLEFYLAMPFATPMEAE L-ARRSLAQ (SEQ ID NO: 245) KEFTVSGNILT(SEQ ID NO: 255) LLEFYLAMPFATPM (SEQ ID NO: 256) AGATGGRGPRGAGA (SEQ ID NO: 257) 8 CEA TYYRPGVNLSLSC (SEQ Galanis et al. Cancer Res. 70(3):875- ID NO: 258) 82 (2010). EIIYPNASLLIQN (SEQ ID Bast et al. Am. J. Obstet. Gynecol. NO: 259) 149(5):553-9 (1984). YACFVSNLATGRNNS Crosti et al. J Immunol. (SEQ ID NO: 260) 176(8):5093-9 (2006). LWWVNNQSLPVSP (SEQ Kobayashi et al. Clin Cancer Res. ID NO: 261) 8(10):3219-25 (2002). LWWVNNQSLPVSP (SEQ Campi et al. Cancer Res. ID NO: 261) 63(23):8481-6 (2003). LWWVNNQSLPVSP (SEQ Bakker et al. Int J Cancer. 62(1):97- ID NO: 261) 102 (1995). EIIYPNASLLIQN (SEQ ID Tsai et al. J Immunol. 158(4):1796- NO: 259) 802 (1997). NSIVKSITVSASG (SEQ Kawakami et al. J Immunol. ID NO: 262) 154(8):3961-8 (1995). KTWGQYWQV (SEQ ID Cox et al. Science. 264(5159):716-9 NO: 263) (1994). (A)MLGTHTMEV (SEQ Kawakami et al. J Immunol. ID NO: 264) 154(8):3961-8 (1995). ITDQVPFSV (SEQ ID NO: Kawakami et al. J Immunol. 265) 161(12):6985-92 (1998). YLEPGPVTA (SEQ ID Skipper et al. J Immunol. NO: 266) 157(11):5027-33 (1996). LLDGTATLRL (SEQ ID Michaux et al. J Immunol. NO: 267) 192(4):1962-71 (2014). VLYRYGSFSV (SEQ ID NO: 268) SLADTNSLAV (SEQ ID NO: 269) RLMKQDFSV (SEQ ID NO: 270) RLPRIFCSC (SEQ ID NO: 271) LIYRRRLMK (SEQ ID NO: 272) ALLAVGATK (SEQ ID NO: 273) IALNFPGSQK (SEQ ID NO: 274) RSYVPLAHR (SEQ ID NO: 275) 9 p53 VVPCEPPEV (SEQ ID NO: Hung et al. Immunol. Rev. 222:43- 276) 69 (2008). 10 Her2/Neu HLYQGCQVV (SEQ ID Nakatsuka et al. Mod. Pathol. NO: 277) 19(6):804-814 (2006). YLVPQQGFFC (SEQ ID Pils et al. Br. J Cancer 96(3):485-91 NO: 278) (2007). PLQPEQLQV (SEQ ID Scardino et al. Eur J Immunol. NO: 279) 31(11):3261-70 (2001). TLEEITGYL (SEQ ID NO: Scardino et al. J Immunol. 280) 168(11):5900-6 (2002). ALIHHNTHL (SEQ ID Kawashima et al. Cancer Res. NO: 281) 59(2):431-5 (1999). PLTSIISAV (SEQ ID NO: Okugawa et al. Eur J Immunol 282) 30(11):3338-46 (2000). VLRENTSPK (SEQ ID NO: 283) TYLPTNASL (SEQ ID NO: 284) 11 EpCAM RYQLDPKFI (SEQ ID NO: Spizzo et al. Gynecol. Oncol. 285) 103(2):483-8 (2006). Tajhna et al. Tissue Antigens. 64(6):650-9 (2004). 12 CA125 ILFTINFTI (SEQ ID NO: Bast et al. Cancer 116(12):2850- 286) 2853 (2010). VLFTINFTI (SEQ ID NO: 287) TLNFTITNL (SEQ ID NO: 288) VLQGLLKPL (SEQ ID NO: 289) VLQGLLRPV (SEQ ID NO: 290) RLDPKSPGV (SEQ ID NO: 291) QLYWELSKL (SEQ ID NO: 292) KLTRGIVEL (SEQ ID NO: 293) QLTNGITEL (SEQ ID NO: 294) QLTHNITEL (SEQ ID NO: 295) TLDRNSLYV (SEQ ID NO: 296) 13 Folate  FLLSLALML (SEQ ID Bagnoli et al. Gynecol. Oncol. receptor a NO: 297) 88:S140-4 (2003). NLGPWIQQV (SEQ ID Pampeno et al. (2016) High-ranking NO: 298) In Silico epitopes [determined by 3 algorithms: BISMAS, IEDB, RANKPEP] unpublished 14 Sperm  ILDSSEEDK (SEQ ID NO: Chiriva-Inernti et al. J. protein 17 299) Immunother. 31(8):693-703 (2008). 15 TADG-12 YLPKSWTIQV (SEQ ID Bellone et al. Cancer 115(4):800-11 NO: 300) (2009). WIHEQMERDLKT SEQ Underwood et al. BBA Mol. Basis of ID NO: 301) Disease. 1502(3):337-350 (2000). 16 MUC-I6 ILFTINFTI (SEQ ID NO: Chekmasova et al. Clin. Cancer Res. 286) 16(14):3594-606 (2010). VLFTINFTI (SEQ ID NO: 287) TLNFTITNL (SEQ ID NO: 288) VLQGLLKPL (SEQ ID NO: 289) VLQGLLRPV (SEQ ID NO: 290) RLDPKSPGV (SEQ ID NO: 291) QLYWELSKL (SEQ ID NO: 292) KLTRGIVEL (SEQ ID NO: 293) QLTNGITEL (SEQ ID NO: 294) QLTHNITEL (SEQ ID NO: 295) TLDRNSLYV (SEQ ID NO: 296) 17 LICAM LLANAYIYV (SEQ ID Hong et al. J. Immunother. 37(2):93- NO: 302) 104(2014). YLLCKAFGA (SEQ ID Pampeno et al. (2016) High-ranking NO: 303) In Silico epitopes [determined by 3 KLSPYVHYT (SEQ ID algorithms: BISMAS, IEDB, NO: 304) RANKPEP] unpublished 18 Mannan-MUC-1 PDTRPAPGSTAPPAHGV Loveland et al. Clin. Cancer Res. TSA (SEQ ID NO: 305) 12(3 Pt 1):869-77 (2006). STAPPVHNV (SEQ ID Godelaine et al. Cancer Immunol NO: 306) Immunother. 56(6):753-9 (2007). LLLLTVLTV (SEQ ID NO: Ma et al. Int J Cancer. 129(10):2427- 307) 34 (2011). PGSTAPPAHGVT (SEQ Wen et al. Cancer Sci. 102(8):1455- ID NO: 308) 61 (2011). Jerome et al. J Immunol. 151(3):1654-62 (1993). Brossart et al. Blood. 93(12):4309- 17 (1999). Hiltbold et al. Cancer Res. 58(22):5066-70 (1998). 19 HERV-K-MEL MLAVISCAV (SEQ ID Schiavetti et al. Cancer Res. NO: 309) 62(19):5510-6 (2002). 20 KK-LC-1 RQKRILVNL (SEQ ID Fukuyama et al. Cancer Res. NO: 310) 66(9):4922-8 (2006). 21 KM-HN-1 NYNNFYRFL (SEQ ID Fukuyama et al. Cancer Res. NO: 311) 66(9):4922-8 (2006). EYSKECLKEF (SEQ ID Monji et al. Clin Cancer Res. 10(19 NO: 312) Pt 1): 6047-57 (2004). EYLSLSDKI (SEQ ID NO: 313) 22 LAGE-1 MLMAQEALAFL (SEQ ID Aamoudse et al. Int J Cancer. NO: 233) 82(3):442-8 (1999). SLLMWITQC (SEQ ID Rimoldi et al. J Immunol. NO: 230) 165(12):7253-61 (2000). LAAQERRVPR (SEQ ID Wang et al. J Immunol. 161(7):3598- NO: 236) 606 (1998). ELVRRILSR (SEQ ID NO: Sun et al. Cancer Immunol 314) Immunother. 55(6):644-52 (2006). APRGVRMAV (SEQ ID Slager et al. Cancer Gene Ther. NO: 315) 11(3):227-36 (2004). SLLMWITQCFLPVF (SEQ Zeng et al. Proc Natl Acad Sci U S ID NO: 244) A. 98(7):3964-9 (2001). QGAMLAAQERRVPRAA Slager et al. J Immunol. EVP-R (SEQ ID NO: 249) 172(8):5095-102 (2004). AADHRQLQLSISSCLQQ Jager et al. J Exp Med. 191(4):625- L (SEQ ID NO: 253) 30 (2000). CLSRRPWKRSWSAGSCP Slager et al. J Immuno!. G-MPHL (SEQ ID NO: 170(3):1490-7 (2003). 316) Wang et al. Immunity. 20(1):107-18 ILSRDAAPLPRPG (SEQ (2004). ID NO: 317) Hasegawa et al. Clin Cancer Res. AGATGGRGPRGAGA 12(6):1921-7 (2006). (SEQ ID NO: 257) 23 MAGE-A4 EVDPASNTY (SEQ ID Kobayashi et al. Tissue Antigens. NO: 318) 62(5):426-32 (2003). GVYDGREHTV (SEQ ID Duffour et al. Eur J Imrnunol. NO: 319) 29(10):3329-37 (1999). NYKRCFPVI (SEQ ID NO: Miyahara et al. Clin Cancer Res. 320) 11(15):5581-9 (2005). SESLICMIF (SEQ ID NO: Ottaviani et al. Cancer Immuno 321) Immunother. 55(7):867-72 (2006) Zang et al. Tissue Antigens. 60(5):365-71 (2002). 24 Spl 7 ILDSSEEDK (SEQ ID NO: Chiriva-Internati et al. Int J Cancer. 299) 107(5):863-5 (2003). 25 SSX-4 INKTSGPKRGKHAWTHR Ayyoub et al. Clin Immunol. LRE (SEQ ID NO: 322) 114(1):70-8 (2005). YFSKKEWEKMKSSEKIV Valmori et al. Clin Cancer Res. YVY (SEQ ID NO: 323) 12(2):398-404 (2006). MKLNYEVMTKLGFKVT LPPF (SEQ ID NO: 324) KHAWTHRLRERKQLVV YEEI (SEQ ID NO: 325) LGFKVTLPPFMRSKRAA DFH (SEQ ID NO: 326) KSSEKIVYVYMKLNYEV MTK (SEQ ID NO: 327) KHAWTHRLRERKQLVV YEEI (SEQ ID NO: 325) 26 TAG-1 SLGWLFLLL (SEQ ID Adair et al. J Immunother. 31(1):7- NO: 328) 17 (2008). LSRLSNRLL (SEQ ID NO: 329) 27 TAG-2 LSRLSNRLL (SEQ ID NO: Adair et al. J Immunother. 31(1):7- 329) 17 (2008).

TABLE 4 Breast cancer Tumor- associated Reported immunogenic No. antigen epitopes Sources 1 ENAH(hMena) TMNGSKSPV (SEQ ID Di Modugno et al. Int. J. Cancer. NO: 330) 109(6):909-18 (2004). 2 mammaglobin-A PLLENVISK (SEQ ID NO: Jaramillo et al. Int. J. Cancer. 331) 102(5):499-506 (2002). 3 NY-BR-I SLSKILDTV (SEQ ID NO: Wang et al. Cancer Res. 66(13):6826- 332) 33 (2006). 4 EpCAM RYQLDPICFI (SEQ ID NO: Gastl et al. Lancet 356(9246):1981-2 285) (2000). Tajima, 2004 5 NY-ESO-1 HLA-A2-restricted peptide Jager et al. Proc. Natl. Acad. Scie. p157-165 (SLLMWITQC U.S.A. 103(39):14453-8 (2006). (SEQ ID NO: 230)), HLA- Gnjatic et al. PNAS Cw3-restricted p92-100 September 26, 2000 vol. 97 no. 20 p. (LAMP-FATPM (SEQ ID 10919 NO: 231)) and HLA-Cw6- Jager et al. J Exp Med. 187(2):265- restricted p80-88 70 (1998). (ARGPESRLL (SEQ ID Chen et al. J Immunol. 165(2):948- NO: 232)) 55 (2000). SLLMWITQC (SEQ ID Valmori et al. Cancer Res. NO: 230) 60(16):4499-506 (2000). MLMAQEALAFL (SEQ ID Aarnoudse et al. Int J Cancer. NO: 233) 82(3):442-8 (1999). YLAMPFATPME (SEQ ID Eikawa et al. Int J Cancer. 132(2):345- NO: 234) 54 (2013). ASGPGGGAPR (SEQ ID Wang et al. J Inununol. 161(7):3598- NO: 235) 606 (1998). LAAQERRVPR (SEQ ID Matsuzald et al. Cancer Immunol NO: 236) Immunother. 57(8)1185-95 (2008). TVSGNILTIR (SEQ ID Ebert et al. Cancer Res. 69(3):1046- NO: 237) 54 (2009). APRGPHGGAASGL (SEQ Eikawa et al. Int J Cancer. 132(2):345- ID NO: 238) 54 (2013). MPFATPMEAEL (SEQ ID Knights et al. Cancer Immunol NO: 239) Immunother. 58(3):325-38 (2009). KEFTVSGNILTI (SEQ ID Jager et al. Cancer Immun. 2:12 NO: 240) (2002). MPFATPMEA (SEQ ID Zeng et al. Proc Natl Acad Sci U S A. NO: 241) 98(7):3964-9 (2001). FATPMEAEL (SEQ ID Mandic et al. J Immunol. 174(3):1751- NO: 242) 9 (2005). FATPMEAELAR (SEQ ID Chen et al. Proc Natl Acad Sci U S A. NO: 243) 101(25):9363-8 (2004). LAMPFATPM (SEQ ID Ayyoub et al. Clin Cancer Res. NO: 231) 16(18):4607-15 (2010). ARGPESRLL (SEQ ID NO:   Slager et al. J Immunol. 172(8):5095- 232) 102 (2004). SLLMWITQCFLPVF (SEQ Mizote et al. Vaccine. 28(32):5338- ID NO: 244) 46 (2010). LLEFYLAMPFATPMEAE Jager et al. J Exp Med. 191(4):625- L-ARRSLAQ (SEQ ID NO: 30 (2000). 245) Zarour et al. Cancer Res. 60(17):4946- EFYLAMPFATPM (SEQ  52 (2000). ID NO: 246) Zeng et al. J Iminunol. 165(2):1153- PGVLLICEFTVSGNILTIR 9(2000). L-TAADHR (SEQ ID NO: Bioley et al. Clin Cancer Res. 247)  15(13):4467-74(2009) RLLEFYLAMPFA (SEQ Zarour et al. Cancer Res. 62(1):213-8 ID NO: 248) (2002). QGAMLAAQERRVPRAA Hasegawa et al. Clin Cancer Res. E-VPR (SEQ ID NO: 249) 12(6):1921-7 (2006). PFATPMEAELARR (SEQ ID NO: 250) PGVLLICEFTVSGNILTIR LT (SEQ ID NO: 251) VLLKEFTVSG (SEQ ID NO: 252) AADHRQLQLSISSCLQQL (SEQ ID NO: 253) LKEFTVSGNILTIRL (SEQ ID NO: 254) PGVLLICEFTVSGNILTIR L-TAADHR (SEQ ID NO: 247) LLEFYLAMPFATPMEAE L-ARRSLAQ (SEQ ID NO: 245) KEFTVSGNILT (SEQ ID NO: 255) LLEFYLAMPFATPM (SEQ ID NO: 256) AGATGGRGPRGAGA (SEQ ID NO: 257) 6 BAGE-1 AARAVFLAL (SEQ ID Boel et al. Immunity. 2(2):167- NO: 333) 75 (1995). 7 HERV-K- MLAVISCAV (SEQ ID Schiavetti et al. Cancer Res. MEL NO: 309) 62(19):5510-6 (2002). 8 KK-LC-1 RQKRILVNL (SEQ ID NO: Fukuyama et al. Cancer Res. 310) 66(9):4922-8 (2006). 9 KM-HN-I NYNNFYRFL (SEQ ID Fukuyama et al. Cancer Res. NO: 311) 66(9):4922-8 (2006). EYSICECLKEF (SEQ ID Monji et al. Clin Cancer Res. 10(18 Pt NO: 312) 1):6047-57 (2004). EYLSLSDKI (SEQ ID NO: 313) 10 LAGE-1 MLMAQEALAFL (SEQ ID Aarnoudse et al. Int J Cancer. NO: 233) 82(3):442-8 (1999). SLLMWITQC (SEQ ID Rimoldi et al. J Immunol. NO: 230) 165(12):7253-61 (2000). LAAQERRVPR (SEQ ID Wang et al. J Immunol. 161(7):3598- NO: 236) 606 (1998). ELVRRILSR (SEQ ID NO: Sun et al. Cancer Immunol 314) Immunother. 55(6):644-52 (2006). APRGVRMAV (SEQ ID Slager et al. Cancer Gene Ther. NO: 315) 11(3):227-36 (2004). SLLMWITQCFLPVF (SEQ Zeng et al. Proc Natl Acad Sci U S A. ID NO: 244) 98(7):3964-9 (2001). QGAMLAAQERRVPRAA Slager et al. J hnmunol. 172(8):5095- EVP-R(SEQ ID NO: 249) 102 (2004). AADHRQLQLSISSCLQQL Jager et al. J Exp Med. 191(4):625- (SEQ ID NO: 253) 30 (2000). CLSRRPWICRSWSAGSCP Slager et al. J Immunol. 170(3):1490- G-MPHL (SEQ ID NO: 316)  7(2003). ILSRDAAPLPRPG (SEQ Wang et al. Immunity. 20(1):107-18 ID NO: 317) (2004). AGATGGRGPRGAGA Hasegawa et al. Clin Cancer Res. (SEQ ID NO: 257) 12(6):1921-7 (2006). 11 MAGE-AI I EADPTGHS (SEQ ID Traversari et al. J Exp Med. NO: 334) 176(5):1453-7 (1992). KVLEYVIKV (SEQ ID Ottaviani et al. Cancer Immunol NO: 335) Immunother. 54(12):1214-20 (2005). SLFRAVITK (SEQ ID NO: Pascolo et al. Cancer Res. 336) 61(10):4072-7 (2001). EVYDGREHSA (SEQ ID Chaux et al. J Immunol. 163(5):2928- NO: 337) 6 (1999). RVRFFFPSL (SEQ ID NO: Luiten et al. Tissue Anitgens. 338) 55(2):49-52 (2000). EADPTGHSY (SEQ ID Luiten et al. Tissue Antigens. NO: 334) 56(1):77-81 (2000). REPVTKAEML (SEQ ID Tanzarella et al. Cancer Res. NO: 339) 59(11):2668-74 (1999). KEADPTGHSY (SEQ ID Stroobant et al. Eur J Immunol. NO: 340) 42(6):1417-28 (2012). DPARYEFLW (SEQ ID Corbiere et al. Tissue Antigens. NO: 341) 63(5):453-7 (2004). ITKKVADLVGF (SEQ ID Goodyear et al. Cancer Immunol NO: 342) Immunother. 60(12):1751-61 (2011). SAFPTTINF (SEQ ID NO: van der Bruggen et al. Eur J Immunol. 343) 24(9):2134-40 (1994). SAYGEPRKL (SEQ ID Wang et al. Cancer Immunol NO: 344) Immunother. 56(6):807-18 (2007). RVRFFFPSL (SEQ ID NO: Chaux et al. J Exp Med. 189(5):767-78 338) (1999). TSCILESLFRAVITK (SEQ Chaux et al. Eur J Immunol. 31(6): ID NO: 345) 1910-6 (2001). PRALAETSYVKVLEY (SEQ ID NO: 346) FLLLKYRAREPVTKAE (SEQ ID NO: 347) EYVIKVSARVRF (SEQ ID NO: 348) 12 MAGE-A2 YLQLVFGIEV (SEQ ID Kawashima et al. Hum Immunol. NO: 349) 59(1):1-14 (1998). EYLQLVFGI (SEQ ID NO: Tahara et al. Clin Cancer Res. 350) 5(8):2236-41 (1999). REPVTKAEML (SEQ ID Tanzarella et al. Cancer Res. NO: 339) 59(11):2668-74 (1999). EGDCAPEEK (SEQ ID Breckpot et al. J Immunol. NO: 351) 172(4):2232-7 (2004). LLKYRAREPVTKAE Chaux et al. J Exp Med. 89(5):767-78 (SEQ ID NO: 352) (1999). 13 mucink PDTRPAPGSTAPPAHGV Jerome et al. J Immunol. 151(3):1654- TSA (SEQ ID NO: 305) 62 (1993). 14 Sp17 ILDSSEEDK (SEQ ID NO: Chiriva-Internati et al. Int J Cancer. 299) 107(5):863-5 (2003). 15 SSX-2 ICASEKHYV (SEQ ID NO: Ayyoub et al. J Immunol. 353) 168(4):1717-22 (2002). EKIQICAFDDIAKYFSK Ayyoub et al. J Immunol. (SEQ ID NO: 354) 172(11):7206-11 (2004). FGRLQGISPKI (SEQ ID Neumann et al. Cancer Immunol NO: 355) Immunother. 60(9):1333-46 (2011). WEKMICASEKIFYVYMK Ayyoub et al. Clin Immunol. RK (SEQ ID NO: 356) 114(1):70-8 (2005). KIFYVYMICRICYEAMT Neumann et al. Int J Cancer. (SEQ ID NO: 357) 112(4):661-8 (2004). KIFYVYMKRKYEAM Ayyoub et al. J Clin Invest. (SEQ ID NO: 358) 113(8):1225-33 (2004). 16 TAG-1 SLGWLFLLL (SEQ ID Adair et al. J Immunother. 31(1):7-17 NO: 328) (2008). LSRLSNRLL (SEQ ID NO: 329) 17 TAG-2 LSRLSNRLL SEQ ID NO: Adair et al. J Immunother. 31(1):7-17 329) (2008). 18 TRAG-3 CEFHACWPAFTVLGE Janjic et al. J Immunol. 177(4):2717- (SEQ ID NO: 359) 27 (2006). 19 Her2/Neu HLYQGCQVV (SEQ ID Nakatsuka et al. Mod. Pathol. NO: 277) 19(6):804-814 (2006). YLVPQQGFFC (SEQ ID Pils et al. Br. J. Cancer 96(3):485-91 NO: 278) (2007). PLQPEQLQV (SEQ ID Scardino et al. Eur J Immunol. NO: 279) 31(11):3261-70 (2001). TLEEITGYL (SEQ ID NO: Scardino et al. J Immunol. 280) 168(11):5900-6 (2002). ALIHHNTHL (SEQ ID NO: Kawashima et al. Cancer Res. 281) 59(2):431-5 (1999). PLTSHSAV (SEQ ID NO: Okugawa et al. Eur J Immunol. 282) 30(11):3338-46 (2000). VLRENTSPK (SEQ ID NO: 283) TYLPTNASL (SEQ ID NO: 284) 20 c-myc Reuschenbach et al. Cancer Immunol. Immunother. 58:1535-1544 (2009) 21 cyclin B1 Reuschenbach et al. Cancer Immunol. Immunother. 58:1535-1544 (2009) 22 MUC1 Reuschenbach et al. Cancer Immunol. Immunother. 58:1535-1544 (2009) 23 p.53 VVPCEPPEV (SEQ ID NO: Hung et al. Immunol. Rev. 222:43-69 276) (2008). http://cancerimmunity.org/peptide/mut ations/ 24 p62 Reuschenbach et al. Cancer Immunol. Immunother. 58:1535-1544(2009) 25 Survivin Reuschenbach et al. Cancer Immunol. Immunother. 58:1535-1544 (2009)

TABLE 5  Testicular cancer Tumor- associated Reported immunogenic No. antigen epitopes Sources 1 CD45 KFLDALISL (SEQ ID NO: Tomita et al. Cancer Sci. 360) 102(4):697-705 (2011). 2 DKK1 ALGGHPLLGV (SEQ ID Qian et al. Blood. (5):1587-94 NO: 361) (2007). 3 PRAME VLDGLDVLL (SEQ ID Kessler et al. J Exp Med. NO: 215), SLYSFPEPEA 193(1):73-88 (2001). (SEQ ID NO: 216), Ikeda et al. Immunity 6(2):199- ALYVDSLFFL (SEQ ID 208 (1997). NO: 217), SLLQHLIGL (SEQ ID NO: 218), LYVDSLFFL (SEQ ID NO: 219) 4 RU2AS LPRWPPPQL (SEQ ID NO: Van Den Eynde et al. J. Exp. 362) Med. 190(12):1793-800 (1999). 5 Telomerase ILAKFLHWL (SEQ ID Vonderheide et al. Immunity NO: 363); 10(6):673-9 (1999). RLVDDFLLV (SEQ ID Miney et al. Proc. Natl. Acad. NO: 364); Sci. U.S.A. 97(9):4796-801 RPGLLGASVLGLDDI (2000). (SEQ ID NO: 365); and Schroers et al. Cancer Res. LTDLQPYMRQFVAHL 62(9):2600-5 (2002). (SEQ ID NO: 366) Schroers et al. Clin. Cancer Res. 9(13):4743-55 (2003).

TABLE 6  Pancreatic cancer Tumor- associated Reported immunogenic No. antigen epitopes Sources 1 ENAH (hMena) TMNGSKSPV (SEQ ID NO:  Di Modugno etal. Int. J. 330) Cancer. 109(6):909-18 (2004). 2 PBF CTACRWICKACQR (SEQ ID Tsukahara et al. Cancer Res. NO: 214) 64(15):5442-8 (2004). 3 K-ras VVVGAVGVG (SEQ ID NO: Gjertsen et al. Int. J. Cancer. 367) 72(5):784-90 (1997). 4 Mesothelin SLLFLLFSL (SEQ ID NO: Le et al. Clin. Cancer Res. 225) 18(3):858-68 (2012). VLPLTVAEV (SEQ ID NO: Hassan et al. Appl. 226) Immunohistochem. Mol. ALQGGGPPY (SEQ ID NO: Morphol. 13(3):243-7 (2005). 227) Thomas et al J Exp Med. LYPKARLAF (SEQ ID NO: 2004 Aug 2; 200(3): 297-306. 228) AFLPWHRLF (SEQ ID NO: 229) 5 mucink PDTRPAPGSTAPPAHGVTSA Jerome et al. J Immunol. (SEQ ID NO: 305) 151(3):1654-62 (1993).

TABLE 7 Liver cancer Tumor- associated Reported immunogenic No antigen epitopes Sources 1 G250/ HLSTAFAR (SEQ ID NO: Vissers et al. Cancer Res. 59(21):5554-9 MN/ 368); (1999). CAIX KIFGSLAFL (SEQ ID NO: Fisk et al. J Exp Med. 181(6):2109-17 369); (1995). IISAVVGIL (SEQ ID NO: Brossart et al. Cancer Res. 58(4):732-6 370); (1998). ALCRWGLLL (SEQ ID NO: Kawashima et al. Hum Immunol. 371); 59(1):1-14 (1998). ILHNGAYSL (SEQ ID NO: Rongcun et al. J Immunol. 163(2):1037- 372); 44 (1999). RLLQETELV (SEQ ID NO: 373); VVKGVVFGI (SEQ ID NO: 374); and YMIMVKCWMI (SEQ ID NO: 375) 2 Hepsin SLLSGDWVL (SEQ ID NO: Guo et al. Scand J Immunol. 78(3):248- 376); 57 (2013). GLQLGVQAV (SEQ ID NO: 377); and PLTEYIQPV (SEQ ID NO: 378) 3 Intestinal SPRWWPTCL (SEQ ID NO: Ronsin et al. J Immunol. 163(1):483-90 carboxyl 379) (1999). esterase 4 alpha- GVALQTMKQ (SEQ ID Butterfield et al. Cancer Res. foetoprote NO: 380); 59(13):3134-42 (1999). in FMNICFIYEI (SEQ ID NO: Pichard et al. J Immunother. 31(3):246- 381); and QLAVSVILRV 53 (2008) (SEQ ID NO: 382) Alisa et al. Clin. Cancer Res. 11(18):6686-94 (2005). 5 M-CSF LPAVVGLSPGEQEY (SEQ Probst-Kepper et al. J Exp Med. ID NO: 383) 193(10):1189-98 (2001). 6 PBF CTACRWIUCACQR (SEQ Tsukahara et al. Cancer Res. ID NO: 214) 64(15):5442-8 (2004). 7 SMA NYARTEDFF (SEQ ID NO: Horiguchi et al. Clin Cancer Res. 384) 8(12):3885-92 (2002). 8 NY-ESO-1 HLA-A2-restricted peptide Jager et al. Proc. Natl. Acad. Scie. p157-165 (SLLMWITQC U.S.A. 103(39):14453-8 (2006). (SEQ ID NO: 230)), HLA- Gnjatic et al. PNAS Cw3-restricted p92-100 September 26, 2000 vol. 97 no. 20 p. (LAMP-FATPM (SEQ ID 10919 NO: 231)) and HLA-Cw6- Jager et al. J Exp Med. 187(2):265- restricted p80-88 70 (1998). (ARGPESRLL (SEQ ID NO: Chen et al. J Immunol. 165(2):948- 232)) 55 (2000). SLLMWITQC (SEQ ID NO: Valmori et al. Cancer Res. 60(16):4499- 230) 506 (2000). MLMAQEALAFL SEQ ID Aarnoudse et al. Int J Cancer. NO: 233) 82(3):442-8 (1999). YLAMPFATPME (SEQ ID Eikawa et al. Int J Cancer. 132(2):345- NO: 234) 54 (2013). ASGPGGGAPR (SEQ ID Wang et al. J Immunol. 161(7):3598- NO: 235) 606 (1998). LAAQERRVPR (SEQ ID Matsuzaki et al. Cancer Immunol NO: 236) Immunother. 57(8)1185-95 (2008). TVSGNILTIR (SEQ ID NO: Ebert et al. Cancer Res. 69(3):1046- 237) 54 (2009). APRGPHGGAASGL (SEQ  Eikawa et al. Int J Cancer. 132(2):345- ID NO: 238) 54 (2013). MPFATPMEAEL (SEQ ID Knights et al. Cancer Immunol NO: 239) Immunother. 58(3):325-38 (2009). KEFTVSGNILTI (SEQ ID Jager et al. Cancer Immun. 2:12 (2002). NO: 240) Zeng et al. Proc Natl Acad Sci U S A. MPFATPMEA (SEQ ID NO: 98(7):3964-9 (2001). 241) Mandic et al. J Immunol. 174(3):1751- FATPMEAEL (SEQ ID NO: 9(2005). 242) Chen et al. Proc Natl Acad Sci U S A. FATPMEAELAR (SEQ ID 101(25):9363-8 (2004). NO: 243) Ayyoub et al. Clin Cancer Res. LAMPFATPM (SEQ ED NO: 16(18):4607-15 (2010). 231) Slager et al. J Immunol. 172(8):5095- ARGPESRLL (SEQ ID NO: 102 (2004). 232) Mizote et al. Vaccine. 28(32):5338- SLLMWITQCFLPVF (SEQ 46 (2010). ID NO: 244) Jager et al. J Exp Med. 191(4):625- LLEFYLAMPFATPMEAEL 30 (2000). -ARRSLAQ (SEQ ID NO: Zarour et al. Cancer Res. 60(17):4946- 245) 52 (2000). EFYLAMPFATPM (SEQ ID Zeng et al. J Immunol. 165(2):1153- NO: 246) 9 (2000). PGVLLKEFTVSGNILTIRL- Bioley et al. Clin Cancer Res. TAADHR (SEQ ID NO: 247) 15(13):4467-74 (2009). RLLEFYLAMPFA (SEQ ID Zarour et al. Cancer Res. 62(1):213-8 NO: 248) (2009).  QGAMLAAQERRVPRAAE Hasegawa et al. Clin Cancer Res. -VPR (SEQ ID NO: 249) 12(6):1921-7 (2006). PFATPMEAELARR (SEQ ID NO: 250) PGVLLICEFTVSGNILTIRL T (SEQ ID NO: 251) VLLICEFTVSG (SEQ ID NO: 252) AADHRQLQLSISSCLQQL (SEQ ID NO: 253) LKEFTVSGNILURL (SEQ ID NO: 254) PGVLLICEFTVSGNILTIRL- TAADHR (SEQ ID NO: 247) LLEFYLAMPFATPMEAEL -ARRSLAQ (SEQ ID NO: 245) KEFTVSGNILT (SEQ ID NO: 255) LLEFYLAMPFATPM (SEQ ID NO: 256) AGATGGRGPRGAGA (SEQ ID NO: 257) 9 LAGE-1 MLMAQEALAFL (SEQ ID Aarnoudse et al. Int J Cancer. NO: 233) 82(3):442-8 (1999). SLLMWITQC (SEQ ID NO: Rimoldi et al. J Immunol. 230) 165(12):7253-61 (2000). LAAQERRVPR (SEQ ID Wang etal. J Immunol. 161(7):3598- NO: 236) 606 (1998). ELVRRILSR (SEQ ID NO: Sun et al. Cancer Immunol Immunother. 314) 55(6):644-52 (2006). APRGVRMAV (SEQ ID Slager et al. Cancer Gene Ther. NO: 315) 11(3):227-36 (2004). SLLMWITQCFLPVF (SEQ Zeng et al. Proc Natl Acad Sci U S A. ID NO: 244) 98(7):3964-9 (2001). QGAMLAAQERRVPRAAE Stager et al. J Immunol. 172(8):5095- VP-R (SEQ ID NO: 249) 102 (2004). AADHRQLQLSISSCLQQL Jager et al. J Exp Med. 191(4):625- (SEQ ID NO: 253) 30 (2000). CLSRRPWKRSWSAGSCP Stager et al. J Immunol. 170(3):1490- G-MPHL (SEQ ID NO: 316) 7 (2003). ILSRDAAPLPRPG (SEQ ID Wang et al. Immunity. 20(1):107-18 NO: 317) (2004). AGATGGRGPRGAGA Hasegawa et al. Clin Cancer Res. (SEQ ID NO: 257) 12(6):1921-7 (2006). 10 HERV-K- MLAVISCAV (SEQ ID NO: Schiavetti et al. Cancer Res. MEL 309) 62(19):5510-6 (2002). 11 KK-LC-1 RQKRILVNL (SEQ ID NO: Fukuyama et al. Cancer Res. 310) 66(9):4922-8 (2006). 12 KM-HN-1 NYNNFYRFL (SEQ ID NO: Fukuyama et al. Cancer Res. 311) 66(9):4922-8 (2006). EYSKECLKEF (SEQ ID Monji et al. Clin Cancer Res. 10(18 Pt NO: 312) 1):6047-57 (2004). EYLSLSDKI (SEQ ID NO: 313) 13 Sp17 ILDSSEEDK (SEQ ID NO: Chiriva-Intemati et al. Int J Cancer. 299) 107(5):863-5 (2003). 14 c-myc Reuschenbach et al. Cancer Immunol. Immunother. 58:1535-1544 (2009) 15 cyclin B1 Reuschenbach et al. Cancer Immunol. Immunother. 58:1535-1544 (2009) 16 p53 VVPCEPPEV (SEQ ID NO: Hung et al. Immunol. Rev. 222:43-69 276) (2008). http://cancerimmunity.org/peptide/mutat ions/ 17 p62 Reuschenbach et al. Cancer Immunol. Immunother. 58:1535-1544 (2009) 18 Survivin Reuschenbach et al. Cancer Immunol. Immunother. 58:1535-1544 (2009)

TABLE 8  Colorectal cancer Tumor- associated Reported immunogenic No. antigen epitopes Sources 1 ENAH (hMe TMNGSKSPV (SEQ I D Di Modupo et al. Int. J Cancer. na) NO: 330) 109(6):909-18 (2004). 2 Intestinal SPRWWPTCL (SEQ ID Ronsin et al. J Immunol. 163(1):483- carboxyl NO: 379) 90 (1999). esterase 3 CASP-5 FLIIWQNTM (SEQ ID NO: Schwitalle et al. Cancer Immun. 4: 14 385) (2004). 4 COA-I TLYQDDTLTLQAAG Maccalli et al. Cancer Res. (SEQ ID NO: 386) 63(20):6735-43 (2003). 5 OGT SLYICFSPFPL (SEQ ID Ripberger. J Clin Immunol. 23(5):415- NO: 387) 23 (2003). 6 OS-9 KELEGILLL (SEQ ID NO: Viperon et al. Cancer Immun. 2: 9 388) (2002). 7 TGF-betaRII RLSSCVPVA (SEQ ID NO: Linnebacher et al. Int. J. Cancer. 389) 93(1):6-11 (2001). 8 NY-ESO-1 HLA-A2-restricted peptide Jager et al. Proc. Natl. Acad. Scie. p157-165 (SLLMWITQC U.S.A. 103(39):14453-8 (2006). (SEQ ID NO: 230)), HLA- Gnjatic et al. PNAS Cw3-restricted p92-100 September 26, 2000 vol. 97 no. 20 p. (LAMP-FATPM (SEQ ID 10919 NO: 231)) and HLA-Cw6-Jager et al. J Exp Med. 187(2):265- restricted p80-88 70 (1998). (ARGPESRLL (SEQ ID Chen et al. J Immunol. 165(2):948- NO: 232)) 55 (2000). SLLMWITQC (SEQ ID Valmori et al. Cancer Res. NO: 230) 60(16):4499-506 (2000). MLMAQEALAFL (SEQ ID Aarnoudse et al. Int J Cancer. NO: 233) 82(3):442-8 (1999). YLAMPFATPME (SEQ ID Eikawa et al. Int J Cancer. 132(2):345- NO: 234) 54 (2013). ASGPGGGAPR (SEQ ID Wang et al. J Immunol. 161(7):3598- NO: 235) 606 (1998). LAAQERRVPR (SEQ ID Matsuzaki et al. Cancer Immunol NO: 236) Immunother. 57(8)1185-95 (2008). TVSGNILTIR (SEQ ID Ebert et al. Cancer Res. 69(3):1046- NO: 237) 54 (2009). APRGPHGGAASGL (SEQ Eikawa et al. Int J Cancer. 132(2):345- ID NO: 238) 54 (2013). MPFATPMEAEL (SEQ ID Knights et al. Cancer Immunol NO: 239) Immunother. 58(3):325-38 (2009). KEFTVSGNILTI (SEQ ID Jager et al. Cancer Immun. 2:12 NO: 240) (2002). MPFATPMEA (SEQ ID Zeng et al. Proc Natl Acad Sci U S A. NO: 241) 98(7):3964-9 (2001). FATPMEAEL (SEQ ID Mandic et al. J Immunol. 174(3):1751- NO: 242) 9 (2005). FATPMEAELAR (SEQ ID Chen et al. Proc Natl Acad Sci U S A. NO: 243) 101(25):9363-8 (2004). LAMPFATPM (SEQ ID Ayyoub et al. Clin Cancer Res. NO: 231) 16(18):4607-15 (2010). ARGPESRLL (SEQ ID NO: Slager et al. J Immunol. 172(8):5095- 232) 102 (2004). SLLMWITQCFLPVF (SEQ Mizote et al. Vaccine. 28(32):5338- ID NO: 244) 46 (2010). LLEFYLAMPFATPMEAE Jager et al. J Exp Med. 191(4):625- L-ARRSLAQ (SEQ ID NO: 30 (2000). 245) Zarour et al. Cancer Res. 60(17):4946- EFYLAMPFATPM (SEQ 52 (2000). ID NO: 246) Zeng et al. J Immunol. 165(2):1153- PGVLLKEFTVSGNILTLR 9(2000). L-TAADHR SEQ ID NO: Bioley et al. Clin Cancer Res. 247) 15(13):4467-74 (2009). RLLEFYLAMPFA (SEQ Zarour et al. Cancer Res. 62(1):213-8 ID NO: 248) (2002). QGAMLAAQERRVPRAA Hasegawa et al. Clin Cancer Res. E-VPR (SEQ ID NO: 249) 12(6):1921-7 (2006). PFATPMEAELARR (SEQ ID NO: 250) PGVLLKEFTVSGNILTIR LT (SEQ ID NO: 251) VLLICEFTVSG (SEQ ID NO: 252) AADHRQLQLSISSCLQQL (SEQ ID NO: 253) LKEFTVSGNILTIRL (SEQ ID NO: 254) PGVLLKEFTVSGNILTIR L-TAADRR (SEQ ID NO: 247) LLEFYLAMPFATPMEAE L-ARRSLAQ (SEQ ID NO: 245) KEFTVSGNILT (SEQ ID NO: 255) LLEFYLAMPFATPM (SEQ ID NO: 256) AGATGGRGPRGAGA (SEQ ID NO: 257) 9 CEA TYYRPGVNLSLSC (SEQ  Duffy, Clin. Chem. 47(4):624-30 ID NO: 258) (2001). EHYPNASLLIQN (SEQ ID Parkhurst et al. Mol. Ther. 19(3):620-6 NO: 259) (2011). YACFVSNLATGRNNS Galanis et al. Cancer Res. 70(3):875- (SEQ ID NO: 260) 82 (2010). LWWVNNQSLPVSP (SEQ Bast et at. Am. J. Obstet. Gynecol. ID NO: 261) 149(5):553-9 (1984). LWWVNNQSLPVSP (SEQ Crosti et al. J Immunol. 176(8):5093-9 ID NO: 261) (2006). LWWVNNQSLPVSP (SEQ Kobayashi et al. Clin Cancer Res. ID NO: 261) 8(10):3219-25 (2002). EHYPNASLLIQN (SEQ ID Campi et al. Cancer Res. 63(23):8481- NO: 259) 6 (2003). NSIVKSITVSASG (SEQ Bakker et at. Int J Cancer. 62(497- ID NO: 262) 102 (1995). KTWGQYWQV (SEQ ID Tsai et at. J Immunol. 158(4):1796- NO:263)  802 (1997). (A)MLGTHTMEV (SEQ ID Kawakami et al. J Immunol. NO: 264) 154(8):3961-8 (1995). ITDQVPFSV (SEQ ID NO: Cox et al. Science. 264(5159):716-9 265) (1994). YLEPGPVTA (SEQ ID Kawakami et al. J Immunol. NO: 266) 154(8):3961-8 (1995). LLDGTATLRL (SEQ ID Kawakami et al. J Immunol. NO: 267) 161(12):6985-92 (1998). VLYRYGSFSV (SEQ ID Skipper et at. J Immunol. NO: 268) 157(11):5027-33 (1996). SLADTNSLAV (SEQ ID Michaux et al. J Immunol. NO: 269) 192(4):1962-71 (2014). RLMKQDFSV (SEQ ID NO: 270) RLPRIFCSC (SEQ ID NO: 271) LIYRRRLMK (SEQ ID NO: 272) ALLAVGATK (SEQ ID NO: 273) IALNFPGSQK (SEQ ID NO: 274) RSYVPLAHR (SEQ ID NO: 275) 10 HERV-K- MLAVISCAV (SEQ ID Schiavetti et al. Cancer Res. MEL NO: 309) 62(19):5510-6 (2002). 11 KK-LC-1 RQICRILVNL (SEQ ID NO: Fukuyama et al. Cancer Res. 310) 66(9):4922-8 (2006). 12 KM-1-HN-1 NYNNFYRFL (SEQ ID Fukuyama et al. Cancer Res. NO: 311) 66(9):4922-8 (2006). EYSICECLICEF (SEQ ID Monji et al. Clin Cancer Res. 10(18 Pt NO: 312) 1):6047-57 (2004). EYLSLSDKI (SEQ ID NO: 313) 13 LAGE-1 MLMAQEALAFL (SEQ ID Aarnoudse et al. Int J Cancer. NO: 233) 82(3):442-8 (1999). SLLMWITQC (SEQ ID Rimoldi et al. J Immunol. NO: 230) 165(12):7253-61 (2000). LAAQERRVPR (SEQ ID Wang et al. J Immunol. 161(7):3598- NO: 236) 606 (1998). ELVRRILSR (SEQ ID NO: Sun et at. Cancer Immunol 314) Immunother. 55(6):644-52 (2006). APRGVRMAV (SEQ ID Slager et al. Cancer Gene Ther. NO: 315) 11(3):227-36 (2004). SLLMWITQCFLPVF (SEQ Zeng et al. Proc Natl Acad Sci U S A. ID NO: 244) 98(7):3964-9 (2001). QGAMLAAQERRVPRAA Slager et al. J Immunol. 172(8):5095- EVP-R (SEQ ID NO: 249) 102 (2004). AADHRQLQLSISSCLQQL Jager et al. J Exp Med. 191(4):625- (SEQ ID NO: 253) 30 (2000). CLSRRPWKRSWSAGSCP Slager et al. J Immunol. 170(3):1490- G-MPHL (SEQ ID NO: 7(2003). 316) Wang et al. Immunity. 20(1):107-18 ILSRDAAPLPRPG (SEQ  (2004). ID NO: 317) Hasegawa etal. Clin Cancer Res. AGATGGRGPRGAGA 12(6):1921-7 (2006). (SEQ ID NO: 257) 14 MAGE-A2 YLQLVFGIEV (SEQ ID Kawashima et al. Hum Immunol. NO: 349) 59(1):1-14 (1998). EYLQLVFGI (SEQ ID NO: Tahara et al. Clin Cancer Res. 350) 5(8):2236-41 (1999). REPVTKAEML (SEQ ID Tanzarella et al. Cancer Res. NO: 339) 59(11):2668-74 (1999). EGDCAPEEK (SEQ ID Breckpot et al. J Immunol. NO: 351) 172(4):2232-7 (2004). LLKYRAREPVTKAE Chaux et al. J Exp Med. 89(5):767-78 (SEQ ID NO: 352) (1999). 15 Sp17 ILDSSEEDK (SEQ ID NO: Chiriva-Internati et al. Int J Cancer. 299) 107(5):863-5 (2003). 16 TAG-1 SLGWLFLLL (SEQ ID Adair et al. J Immunother. 31(1):7-17 NO: 328) (2008). LSRLSNRLL (SEQ ID NO: 329) 17 TAG-2 LSRLSNRLL (SEQ ID NO: Adair et al. J Immunother. 31(1):7-17 329) (2008). 18 c-myc Reuschenbach et al. Cancer Immunol. Immunother. 58:1535-1544 (2009) 19 cyclin B1 Reuschenbach et al. Cancer Immunol. Immunother. 58:1535-1544 (2009) 20 MUC1 Reuschenbach et al. Cancer Imnumol. Immunother. 58:1535-1544 (2009) 21 p53 VVPCEPPEV (SEQ ID NO: Hung et al. Immunol. Rev. 222:43-69 276) (2008). http://cancerimmunity.org/peptide/mut ations/ 22 p62 Reuschenbach et al. Cancer Immunol. Immunother. 58:1535-1544 (2009) 23 Survivin Reuschenbach et al. Cancer Immunol. Immunother. 58:1535-1544 (2009) 24 gp70 Castle et al., BMC Genomics 15:190 (2014)

TABLE 9 Thyroid cancer Tumor- associated Reported immunogenic No.  antigen epitopes Sources 1 CALCA VLLQAGSLHA (SEQ ID NO: El Hage et al. Proc. Natl. 390) Acad. Sci. U.S.A. 105(29):10119-24 (2008). 2 NY-ESO-1 HLA-A2-restricted peptide Jager et al. Proc. Natl. Acad. p157-165 (SLLMWITQC SEQ Scie. U.S.A. 103(39):14453-8 ID NO: 230)), HLA-Cw3- (2006). restricted p92-100 (LAMP- Gnjatic et al. PNAS FATPM (SEQ ID NO: 231)) and September 26,2000 vol. 97 HLA-Cw6-restricted p80-88 no. 20 p. 10919 (ARGPESRLL (SEQ ID NO: Jager et al. J Exp Med. 232)) 187(2):265-70 (1998). SLLMWITQC (SEQ ID NO: Chen et al. J Immunol. 230) 165(2):948-55 (2000). MLMAQEALAFL (SEQ ID Valmori et al. Cancer Res. NO: 233) 60(16):4499-506 (2000). YLAMPFATPME (SEQ ID NO: Aarnoudse et al. Int J Cancer. 234) 82(3):442-8 (1999). ASGPGGGAPR (SEQ ID NO: Eikawa et al. Int J Cancer. 235) 132(2):345-54 (2013). LAAQERRVPR (SEQ ID NO: Wang et al. J Immunol. 236) 161(7):3598-606 (1998). TVSGNILTIR (SEQ ID NO: Matsuzaki et al. Cancer 237) Immunol Immunother. APRGPHGGAASGL (SEQ ID 57(8)1185-95 (2008). NO: 238) Ebert et al. Cancer Res. MPFATPMEAEL (SEQ ID NO: 69(3):1046-54 (2009). 239) Eikawa et al. Int J Cancer. KEFTVSGNILTI (SEQ ID NO: 132):345-54 (2013). 240) Knights et al. Cancer MPFATPMEA (SEQ ID NO: Immunol Immunother. 241) 58(3):325-38 (2009). FATPMEAEL (SEQ ID NO:  Jager et al. Cancer Immun. 242) 2:12 (2002). FATPMEAELAR(SEQ ID NO: Zeng et al. Proc Natl Acad Sci 243) U S A. 98(7):3964-9 (2001). LAMPFATPM (SEQ ID NO: Mandic et al. J Immunol. 231) 174(3):1751-9 (2005). ARGPESRLL (SEQ ID NO: Chen et al. Proc Natl Acad 232) Sci U S A. 101(25):9363- SLLMWITQCFLPVF (SEQ ID 8(2004). NO: 244) Ayyoub et al. Clin Cancer LLEFYLAMPFATPMEAEL- Res. 16(18):4607-15 (2010). ARRSLAQ (SEQ ID NO: 245) Slager et al. J Immunol. EFYLAMPFATPM (SEQ ID 172(8):5095-102 (2004). NO: 246) Mizote et al. Vaccine. PGVLLKEFTVSGNILTIRL- 28(32):5338-46 (2010). TAADIAR (SEQ ID NO: 247) Jager et al. J Exp Med. RLLEFYLAMPFA (SEQ ID 191(4):625-30 (2000). NO: 248) Zarour et al. Cancer Res. 60(17):4946-52 (2000). QGAMLAAQERRVPRAAE- Zeng et al. J Immunol. VPR (SEQ ID NO: 249) 165(2):1153-9 (2000). PFATPMEAELARR (SEQ ID Bioley et al. Clin Cancer Res. NO: 250) 15(13):4467-74 (2009). PGVLLKEFTVSGNILTIRLT Zarour et al. Cancer Res. (SEQ ID NO: 251) 62(1):213-8 (2002). VLLICEFTVSG (SEQ ID NO: Hasegawa et al. Clin Cancer 252) Res. 12(6):1921-7 (2006). AADHRQLQLSISSCLQQL (SEQ ID NO: 253) LKEFTVSGNILTIRL (SEQ ID NO: 254) PGVLLICEFTVSGNILTIRL- TAADHR (SEQ ID NO: 247) LLEFYLAMPFATPMEAEL- ARRSLAQ (SEQ ID NO: 245) KEFTVSGNILT (SEQ ID NO: 255) LLEFYLAMPFATPM (SEQ ID NO: 256) AGATGGRGPRGAGA (SEQ ID NO: 257) 3 HERV-K-MEL MLAVISCAV (SEQ ID NO: Schiavetti et al. Cancer Res. 309) 62(19):5510-6 (2002). 4 KK-LC-1 RQKRILVNL (SEQ ID NO: Fukuyama et al. Cancer Res. 310) 66(9):4922-8 (2006). 5 KM-HN-1 NYNNFYRFL (SEQ ID NO: Fukuyama et al. Cancer Res. 311) 66(9):4922-8 (2006). EYSKECLKEF (SEQ ID NO: Monji et al. Clin Cancer Res. 312) 10(18 Pt 1):6047-57 (2004). EYLSLSDKI (SEQ ID NO: 13) 6 AGE-1 MLMAQEALAFL (SEQ ID Aarnoudse et al. Int J Cancer. NO: 233) 82(3):442-8 (1999). SLLMWITQC (SEQ ID NO: Rimoldi et al. J Immunol. 230) 165(12):7253-61 (2000). LAAQERRVPR (SEQ ID NO: Wang et al. J Immunol 236) 161(7):3598-606 (1998). ELVRRILSR (SEQ ID NO: 314) Sun et al. Cancer Immunol APRGVRMAV (SEQ ID NO: Immunother. 55(6):644-52 315) (2006). SLLMWITQCFLPVF (SEQ ID Slager et al. Cancer Gene NO: 244) Ther. 11(3):227-36 (2004). QGAMLAAQERRVPRAAEVP- Zeng et al. Proc Nat! Acad Sci R (SEQ ID NO: 249) U S A. 98(7):3964-9 (2001). AADHRQLQLSISSCLQQL Slager et al. J Immunol. (SEQ ID NO: 253) 172(8):5095-102 (2004). CLSRRPWICRSWSAGSCPG- Jager et al. J Exp Med. MPHL (SEQ ID NO: 316) 191(4):625-30 (2000). ILSRDAAPLPRPG (SEQ ID Slager et al. J Immunol. NO: 317) 170(3):1490-7 (2003). AGATGGRGPRGAGA (SEQ Wang et al. Immunity. ID NO: 257) 20(1):107-18 (2004). Hasegawa et al. Clin Cancer Res. 12(6):1921-7 (2006). 7 Spl 7 ILDSSEEDK (SEQ ID NO: 299) Chiriva-Intemati et al. Int J Cancer. 107(5):863-5 (2003).

TABLE 10  Lung cancer Tumor- Reported  associated immunogenic No. antigen epitopes Sources 1 CD274 LLNAFTVTV (SEQ ID NO: Munir et al. Cancer Res. 73(6):1764-76 391) (2013). 2 mdm-2 VLFYLGQY (SEQ ID NO: Asai et al. Cancer Immun. 2: 3 (2002). 392) 3 alpha- FIASNGVKLV (SEQ ID Echchakir et al. Cancer Res. actinin-4 NO: 393) 61(10):4078-83 (2001). 4 Elongation ETVSEQSNV (SEQ ID NO: Hogan et al. Cancer Res. 58(22):5144- factor 2 394) 50 (1998). (squamous cell carcinoma of the lung) 5 ME1(non- FLDEFMEGV (SEQ ID NO: Karanikas et al. Cancer Res. small cell 395) 61(9):3718-24 (2001). lung carcinoma) 6 NFYC QQITKTEV (SEQ 1D NO: Takenoyama et al. Int. J Cancer. (squamous 396) 118(8):1992-7 (2006). cell carcinoma of the lung) 7 NY-ESO-1 HLA-A2-restricted peptide Jager et al. Proc. Natl. Acad. Scie. p157-165 (SLLMWITQC U.S.A. 103(39):14453-8 (2006). (SEQ ID NO: 230)), HLA- Gnjatic et al. PNAS Cw3-restricted p92-100 September 26,2000 vol. 97 no. 20 p. LAMP-FATPM (SEQ ID 10919 NO: 231)) and HLA-Cw6- Jager et al. J Exp Med. 187(2):265- restricted p80-88 70 (1998). (ARGPESRLL (SEQ ID Chen et al. J Immunol. 165(2):948- NO: 232)) 55 (2000). SLLMWITQC (SEQ ID NO: Valmori et al. Cancer Res. 230) 60(16):4499-506 (2000). MLMAQEALAFL (SEQ ID Aamoudse et al. Int J Cancer. NO: 233) 82(3):442-8 (1999). YLAMPFATPME (SEQ ID Eikawa et al. Int J Cancer. 132(2): NO: 234) 345-54 (2013). ASGPGGGAPR (SEQ ID Wang et al. J Immunol. 161(7):3598- NO: 235) 606 (1998). LAAQERRVPR (SEQ ID Matsuzalci et al. Cancer Immunol NO: 236) Immunother. 57(8)1185-95 (2008). TVSGNILTIR (SEQ ID NO: Ebert et al. Cancer Res. 69(3):1046- 237) 54 (2009). APRGPHGGAASGL (SEQ Eikawa et al. Int J Cancer. 132(2): ID NO: 238) 345-54 (2013). MPFATPMEAEL (SEQ ID Knights et al. Cancer Immunol NO: 239) Immunother. 58(3):325-38 (2009). KEFTVSGNILTI (SEQ ID Jager et al. Cancer Immun. 2:12 NO: 240) (2002). MPFATPMEA (SEQ ID Zeng et al. Proc Natl Acad Sci U S A. NO: 241) 98(7):3964-9 (2001). FATPMEAEL (SEQ ID NO: Mandic et al. J Immunol. 174(3):1751- 242) 9 (2005). FATPMEAELAR (SEQ ID Chen et al. Proc Natl Acad Sci U S A. NO: 243) 101(25):9363-8 (2004). LAMPFATPM (SEQ ID Ayyoub et al. Clin Cancer Res. NO: 231) 16(18):4607-15 (2010). ARGPESRLL (SEQ ID NO: Slager et al. J Immunol. 172(8):5095- 232) 102(2004). SLLMWITQCFLPVF (SEQ Mizote et al. Vaccine. 28(32):5338- ID NO: 244) 46 (2010). LLEFYLAMPFATPMEAE Jager et al. J Exp Med. 191(4):625- L-ARRSLAQ (SEQ ID NO: 30 (2000). 245) Zarour et al. Cancer Res. 60(17):4946- EFYLAMPFATPM (SEQ 52 (2000). ID NO: 246) Zeng et al. J Immunol. 165(2):1153- PGVLLKEFTVSGNILTIRL 9(2000). -TAADHR (SEQ ID NO: Bioley et al. Clin Cancer Res. 247) 15(13):4467-74 (2009). RLLEFYLAMPFA (SEQ ID Zarour et al. Cancer Res. 62(1):213-8 NO: 248) (2002). QGAMLAAQERRVPRAA Hasegawa et al. Clin Cancer Res. E-VPR SEQ ID NO: 249) 12(6):1921-7 (2006). PFATPMEAELARR (SEQ ID NO: 250) PGVLLKEFTVSGNILTIRL T (SEQ ID NO: 251) VLLKEFTVSG (SEQ ID NO: 252) AADHRQLQLSISSCLQQL (SEQ ID NO: 253) LKEFTVSGNILTIRL (SEQ ID NO: 254) PGVLLKEFTVSGNILTIRL -TAADHR (SEQ ID NO: 247) LLEFYLAMPFATPMEAE L-ARRSLAQ (SEQ ID NO: 245) KEFTVSGNILT (SEQ ID NO: 255) LLEFYLAMPFATPM (SEQ ID NO: 256) AGATGGRGPRGAGA (SEQ ID NO: 257) 8 GAGE-1,2,8 YRPRPRRY (SEQ ID NO: Van den Eynde et al. J Exp Med. 397) 182(3):689-98 (1995). 9 HERV-K- MLAVISCAV (SEQ ID NO: Schiavetti et al. Cancer Res. MEL 309) 62(19):5510-6 (2002). 10 KK-LC-1 RQKRILVNL (SEQ ID NO: Fukuyama et al. Cancer Res. 310) 66(9):4922-8 (2006). 11 KM-HN-1 NYNNFYRFL (SEQ ID NO: Fukuyama et al. Cancer Res. 311) 66(9):4922-8 (2006). EYSKECLKEF (SEQ ID Monji et al. Clin Cancer Res. 10(18 Pt NO: 312) 1):6047-57 (2004). EYLSLSDKI SEQ ID NO: 313) 12 LAGE-1 MLMAQEALAFL (SEQ ID Aamoudse et al. Int J Cancer. NO: 233) 82(3):442-8 (1999). SLLMWITQC (SEQ ID NO: Rimoldi et al. J Immunol. 230) 165(12):7253-61 (2000). LAAQERRVPR (SEQ ID Wang etal. J Immunol. 161(7):3598- NO: 236) 606 (1998). ELVRRILSR (SEQ ID NO: Sun et al. Cancer Immunol 314) Immunother. 55(6):644-52 (2006). APRGVRMAV (SEQ ID Slager et al. Cancer Gene Ther. NO: 315) 11(3):227-36 (2004). SLLMWITQCFLPVF (SEQ Zeng et al. Proc Natl Acad Sci U S A. ID NO: 244) 98(7):3964-9 (2001). QGAMLAAQERRVPRAA Slager et al. J Immunol. 172(8):5095- EVP-R (SEQ ID NO: 249) 102 (2004). AADITRQLQLSISSCLQQL Jager et al. J Exp Med. 191(4):625- (SEQ ID NO: 253) 30 (2000). CLSRRPWKRSWSAGSCP Slager et al. J Immunol. 170(3):1490- G-MPHL (SEQ ID NO: 316) 7 (2003). ILSRDAAPLPRPG (SEQ Wang et al. Immunity. 20(1):107-18 ID NO: 317) (2004). AGATGGRGPRGAGA Hasegawa et al. Clin Cancer Res. (SEQ ID NO: 257) 12(6):1921-7 (2006). 13 MAGE-A2 YLQLVFGIEV (SEQ ID Kawashima et al. Hum Immunol NO: 349) 59(1):1-14 (1998). EYLQLVFGI(SEQ ID NO: Tahara et al. Clin Cancer Res. 350) 5(8):2236-41 (1999). REPVTKAEML (SEQ ID Tanzarella et al. Cancer Res. NO: 339) 59(11):2668-74 (1999). EGDCAPEEK (SEQ ID NO: Breckpot et al. J Immunol 351) 172(4):2232-7 (2004). LLKYRAREPVTKAE (SEQ Chaux et al. J Exp Med. 89(5):767-78 ID NO: 352) (1999). 14 MAGE-A6 MVKISGGPR (SEQ ID NO: Zorn et al. Eur J Immunol. 29(2):602-7 (squamous 398) (1999). cell lung EVDPIGHVY (SEQ ID NO: Benlalam et al. J Immunol. carcinoma) 399) 171(11):6283-9 (2003). REPVTKAEML (SEQ ID Tanzarella et al. Cancer Res. NO: 339) 59(11):2668-74 (1999). EGDCAPEEK (SEQ ID NO: Breckpot et al. J Immunol. 351) 172(4):2232-7 (2004). ISGGPRISY (SEQ ID NO: Vantomme et al. Cancer Immun. 400) 3:17 (2003). LLKYRAREPVTKAE (SEQ Chaux et al. J Exp Med. 189(5):767- ID NO: 352) 78 (1999). 15 Sp17 ILDSSEEDK (SEQ ID NO: Chiriva-Internati et al. Int J Cancer. 299) 107(5):863-5 (2003). 16 TAG-1 SLGWLFLLL (SEQ ID NO: Adair et al. J Immunother. 31(1):7-17 328) (2008). LSRLSNRLL (SEQ ID NO: 329) 17 TAG-2 LSRLSNRLL (SEQ ID NO: Adair et al. J Immunother. 31(1):7-17 329) (2008). 18 TRAG-3 CEFHACWPAFTVLGE Janjic et al. J Immunol. 177(4):2717-27 (SEQ ID NO: 359) (2006). 19 XAGE- RQKKIRIQL (SEQ ID NO: Ohue et al. Int J Cancer. 131(5):E649- 1b/GAGED2a 401) 58 (2012). (non-small HLGSRQKKIRIQLRSQ Shimono et al. Int J Oncol. 30(4):835- cell lung (SEQ ID NO: 402) 40 (2007). cancer) CATWKVICKSCISQTPG (SEQ ID NO: 403) 20 c-myc Reuschenbach et al. Cancer Immunol. Immunother. 58:1535-1544 (2009) 21 cyclin B1 Reuschenbach et al. Cancer Immunol. Immunother. 58:1535-1544(2009) 22 Her2/Neu HLYQGCQVV (SEQ ID Nakatsuka et al. Mod. Pathol. NO: 277) 19(6):804-814 (2006). YLVPQQGFFC (SEQ ID Pils et al. Br. J. Cancer 96(3):485-91 NO: 278) (2007). PLQPEQLQV (SEQ ID NO: Scardino et al. Eur J Immunol. 279) 31(11):3261-70 (2001). TLEEITGYL (SEQ ID NO: Scardino et al. J Immunol. 280) 168(11):5900-6 (2002). ALIHHNTHL (SEQ ID NO: Kawashima et al. Cancer Res. 281) 59(2):431-5 (1999). PLTSIISAV (SEQ ID NO: Olcugawa et al. Eur J Immunol. 282) 30(11):3338-46 (2000). VLRENTSPK (SEQ ID NO: 283) TYLPTNASL (SEQ ID NO: 404) 23 MUC1 Reuschenbach et al. Cancer Immunol. Immunother. 58:1535-1544 (2009) 24 p53 VVPCEPPEV (SEQ ID NO: Hung et al. Immunol. Rev. 222:43-69 276) (2008). http://cancerimmunity.org/peptide/ mutations/ 25 p62 Reuschenbach et al. Cancer Immunol. Immunother. 58:1535-1544 (2009) 26 Survivin Reuschenbach et al. Cancer Immunol. Immunother. 58:1535-1544 (2009)

TABLE 11 Prostate cancer Tumor- Reported  associated immunogenic No. antigen epitopes Sources 1 DKK1 ALGGHPLLGV (SEQ ID NO: Qian et al. Blood. 361) 110(5):1587-94 (2007). 2 ENAH (hMena) TMNGSKSPV (SEQ ID NO: Di Modugno et al. Int. J. 330) Cancer. 109(6):909-18 (2004). 3 Kallikrein 4 FLGYLILGV (SEQ ID NO: Wilkinson et al. Cancer 210); SVSESDTIRSISIAS (SEQ Immunol Immunother. ID NO: 211); 61(2):169-79 (2012). LLANGRMPTVLQCVN (SEQ Hural et al. J. Immunol. ID NO: 212); and 169(1):557-65 (2002). RMPTVLQCVNVSVVS (SEQ ID NO: 213) 4 PSMA NYARTEDFF (SEQ ID NO: Horiguchi et al. Clin Cancer 384) Res. 8(12):3885-92 (2002). 5 STEAP1 MIAVFLPIV (SEQ ID NO: 405) Rodeberg et al. Clin. Cancer and HQQYFYKIPILVINK (SEQ Res. 11(12):4545-52 (2005). ID NO: 406) Kobayashi et al. Cancer Res. 67(11):5498-504 (2007). 6 PAP FLFLLFFWL (SEQ ID NO: Olson et al. Cancer 407); Immunol Immunother. TLMSAMTNL (SEQ ID NO: 59(6):943-53 (2010). 408); and ALDVYNGLL (SEQ ID NO: 409) 7 PSA (prostate FLTPKKLQCV (SEQ ID NO: Correale et al. J Natl. carcinoma) 410) and VISNDVCAQV (SEQ Cancer Inst. 89(4):293-300 ID NO: 411) (1997). 8 NY-ESO-1 HLA-A2-restricted peptide Jager et al. Proc. Natl. Acad. p157-165 (SLLMWITQC (SEQ Scie. U.S.A. 103(39):14453- ID NO: 230)), HLA-Cw3- 8 (2006). restricted p92-100 (LAMP- Gnjatic et al. PNAS FATPM (SEQ ID NO: 231)) and September 26,2000 vol. 97 HLA-Cw6-restricted p80-88 no. 20p. 10919 (ARGPESRLL (SEQ ID NO: Jager et al. J Exp Med. 232)) 187(2):265-70 (1998). SLLMWITQC (SEQ ID NO: Chen et al. J Immunol. 230) 165(2):948-55 (2000). MLMAQEALAFL (SEQ ID Valmori et al. Cancer Res. NO: 233) 60(16):4499-506 (2000). YLAMPFATPME (SEQ ID NO: Aamoudse et al. Int J 234) Cancer. 82(3):442-8 (1999). ASGPGGGAPR (SEQ ID NO: Eikawa et al. Int J Cancer. 235) 132(2):345-54 (2013). LAAQERRVPR (SEQ ID NO: Wang et al. J Immunol. 236) 161(7):3598-606(1998). TVSGNILTIR (SEQ ID NO: Matsuzaki et al. Cancer 237) Immunol Immunother. APRGPHGGAASGL (SEQ ID 57(8)1185-95 (2008). NO: 238) Ebert et al. Cancer Res. MPFATPMEAEL (SEQ ID NO: 69(3):1046-54 (2009). 239) Eilcawa et al. Int J Cancer. KEFTVSGNILTI (SEQ ID NO: 132(2):345-54 (2013). 240) Knights et al. Cancer MPFATPMEA (SEQ ID NO: Immunol Immunother. 241) 58(3):325-38 (2009). FATPMEAEL (SEQ ID NO: Jager et al. Cancer Immun. 242) 2:12 (2002). FATPMEAELAR (SEQ ID NO: Zeng et al. Proc Natl Acad 243) Sci U S A. 98(7):3964- LAMPFATPM (SEQ ID NO: 9(2001). 231) Mandic et al. J Immunol. ARGPESRLL (SEQ ID NO: 174(3):1751-9 (2005). 232) Chen et al. Proc Natl Acad SLLMWITQCFLPVF (SEQ ID Sci U S A. 101(25):9363- NO: 244) 8 (2004). LLEFYLAMPFATPMEAEL- Ayyoub et al. Clin Cancer ARRSLAQ (SEQ ID NO: 245) Res. 16(18):4607-15 (2010). EFYLAMPFATPM (SEQ ID Slager et al. J Immunol. NO: 246) 172(8):5095-102 (2004). PGVLLKEFTVSGNILTLRL- Mizote et al. Vaccine. TAADHR (SEQ ID NO: 247) 28(32):5338-46 (2010). RLLEFYLAMPFA (SEQ ID Jager et al. J Exp Med. NO: 248) 191(4):625-30 (2000). QGAMLAAQERRVPRAAE- Zarour et al. Cancer Res. VPR (SEQ ID NO: 249) 60(17):4946-52 (2000). PFATPMEAELARR (SEQ ID Zeng et al. J Immunol. NO: 250) 165(2):1153-9 (2000). PGVLLKEFTVSGNILTIRLT Bioley et al. Clin Cancer (SEQ ID NO: 251) Res. 15(13):4467-74 (2009). VLLKEFTVSG (SEQ ID NO: Zarour et al. Cancer Res. 252) 62(1):213-8 (2002). AADHRQLQLSISSCLQQL Hasegawa et al. Clin Cancer (SEQ ID NO: 253) Res. 12(6):1921-7 (2006). LKEFTVSGNILTIRL (SEQ ID NO: 254) PGVLLICEFTVSGNILTERL- TAADHR (SEQ ID NO: 247) LLEFYLAMPFATPMEAEL- ARRSLAQ (SEQ ID NO: 245) KEFTVSGNILT (SEQ ID NO: 255) LLEFYLAMPFATPM (SEQ ID NO: 256) AGATGGRGPRGAGA (SEQ ID NO: 257) 9 BAGE-1(non- AARAVFLAL (SEQ ID NO: Boel et al. Immunity. small cell lung 333) 2(2):167-75 (1995). carcinoma) 10 GAGE-1,2,8 YRPRPRRY (SEQ ID NO: 397) Van den Eynde et al. J Exp (non-small cell Med. 182(3):689-98 (1995). lunch carcinoma) 11 GAGE-3,4,5,6,7 YYWPRPRRY (SEQ ID NO: De Backer et al. Cancer (lung squamous 412) Res. 59(13):3157-65 (1999). cell carcinoma and lung adenocarcinoma) 12 HERV-K-MEL MLAVISCAV (SEQ ID NO: Schiavetti et al. Cancer Res. 309) 62(19):5510-6 (2002). 13 KK-LC-1 RQKRILVNL (SEQ ID NO: Fukuyama et al. Cancer Res. 310) 66(9):4922-8 (2006). 14 KM-HN-1 NYNNFYRFL (SEQ ID NO: Fukuyama et al. Cancer Res. 311) 66(9):4922-8 (2006). EYSKECLKEF (SEQ ID NO: Monji et al. Clin Cancer 312) Res. 10(18 Pt 1):6047-57 EYLSLSDKI (SEQ ID NO: 313) (2004). 15 LAGE-1 MLMAQEALAFL (SEQ ID Aamoudse et al. Int J NO: 233) Cancer. 82(3):442-8 (1999). SLLMWITQC (SEQ ID NO: Rimoldi et al. J Immunol. 230) 165(12):7253-61 (2000). LAAQERRVPR (SEQ ID NO: Wang et al. J Immunol. 236) 161(7):3598-606 (1998). ELVRRILSR (SEQ ID NO: 314) Sun et al. Cancer Immunol APRGVRMAV (SEQ ID NO: Immunother. 55(6):644-52 315) (2006). SLLMWITQCFLPVF (SEQ ID Slager et al. Cancer Gene NO: 244) Ther. 11(3):227-36 (2004). QGAMLAAQERRVPRAAEVP- Zeng et al. Proc Natl Acad R (SEQ ID NO: 249) Sci U S A. 98(7):3964- AADHRQLQLSISSCLQQL 9(2001). (SEQ ID NO: 253) Slager et al. J Immunol. CLSRRPWKRSWSAGSCPG- 172(8):5095-102 (2004). MPHL (SEQ ID NO: 316) Jager et al. J Exp Med. ILSRDAAPLPRPG (SEQ ID 191(4):625-30 (2000). NO: 317) Slager et al. J Immunol. AGATGGRGPRGAGA (SEQ 170(3):1490-7 (2003). ID NO: 257) Wang et al. Immunity. 20(1):107-18 (2004). Hasegawa et al. Clin Cancer Res. 12(6):1921-7 (2006). 16 Sp17 ILDSSEEDK (SEQ ID NO: 299) Chiriva-Intemati et al. Int J Cancer. 107(5):863-5 (2003).

TABLE 12 Kidney cancer Tumor- Reported  associated immunogenic No. antigen epitopes Sources 1 FGF5 NTYASPRFK (SEQ ID NO: Hanada et al. Nature. 413) 427(6971):252-6 (2004). 2 Hepsin SLLSGDWVL (SEQ ID NO: Guo et al. Scand J Immunol. 376); 78(3):248-57 (2013). GLQLGVQAV (SEQ ID NO: 377); and PLTEYIQPV (SEQ ID NO: 378) 3 Intestinal SPRWWPTCL (SEQ ID NO: Ronsin et al. J Immunol carboxyl 379) 163(1):483-90 (1999). esterase 4 M-CSF LPAVVGLSPGEQEY (SEQ Probst-Kepper et al. J Exp ID NO: 383) Med. 193(10):1189-98 (2001). 5 RU2AS LPRWPPPQL (SEQ ID NO: Van Den Eynde et al. J. Exp. 362) Med. 190(12):1793-800 (1999). 6 hsp70-2 renal SLFEGIDIYT (SEQ ID NO: Gaudin et al. J. Immunol. cell carcinoma) 414) 162(3):1730-8 (1999). 7 Mannan-MUC-I PDTRPAPGSTAPPAHGVTSA Loveland et al. Clin. Cancer (renal cell (SEQ ID NO: 305) Res. 12(3 Pt 1):869-77 (2006). carcinoma) STAPPVHNV (SEQ ID NO: Loveland et al. Clin. Cancer 306) Res. 12(3 Pt 1):869-77 (2006). LLLLTVLTV (SEQ ID NO: Godelaine et al. Cancer 307) Immunol Immunother. PGSTAPPAHGVT (SEQ ID 56(6):753-9 (2007). NO: 308) Ma et al. Int J Cancer. 129(10):2427-34 (2011). Wen et al. Cancer Sci. 102(8):1455-61 (2011). Jerome et al. J Immunol. 151(3):1654-62 (1993). Brossart et al. Blood. 93(12):4309-17 (1999). Hiltbold et al. Cancer Res. 58(22):5066-70 (1998). 8 MAGE-A9 (renal ALSVMGVYV (SEQ ID NO: Oehlrich et al. Int J Cancer. cell carcinoma) 415) 117(2):256-64 (2005).

TABLE 13  Melanoma Tumor- Reported associated immunogenic No. antigen epitopes Sources 1 Hepsin SLLSGDWVL (SEQ ID NO: Guo et at. Scand J Immunol. 376); 78(3):248-57 (2013). GLQLGVQA (SEQ ID NO: 416); and PLTEYIQPV (SEQ ID NO: 378) 2 ARTC1 YSVYFNLPADTIYTN Wang et al J Immunol. 174(5):2661- (SEQ ID NO: 417) 70 (2005). 3 B-RAF EDLTVIUGDFGLATEKSR Sharkey et at. Cancer Res. WSGSHQFEQLS (SEQ ID 64(5):1595-9 (2004). NO: 418) 4 beta-catenin SYLDSGIHF (SEQ ID NO: Robbins et al. J. Exp. Med. 419) 183(3):1185-92 (1996). 5 Cdc27 FSWAMDLDPKGA (SEQ Wang et at. Science. ID NO: 420) 284(5418):1351-4 (1999). 6 CDK4 ACDPHSGHFV (SEQ ID Wolfel et at. Science. NO: 421) 269(5228):1281-4 (1995). 7 CDK12 CILGKLFTK SEQ ID NO: Robbins et at. Nat Med. 19(6):747- 422) 52. (2013). 8 CDKN2A AVCPWTWLR (SEQ ID Huang et al. J Immunol. NO: 423) 172(10):6057-64 (2004). 9 CLPP ILDKVLVHL SEQ ID NO: Corbiere et al. Cancer Res. 424) 71(4):1253-62 (2011). 10 CSNK1A1 GLFGDIYLA (SEQ ID NO: Robbins et at. Nat Med. 19(6):747- 425) 52 (2013). 11 FN1 MIFEKHGFRRTTPP (SEQ Wang et al. J Exp Med. ID NO: 426) 195(11):1397-406 (2003). 12 GAS7 SLADEAEVYL (SEQ ID Robbins, et al. Nat Med. 19(6):747- NO: 427) 52 (2013). 13 GPNMB TLDWLLQTPK (SEQ ID Lennerz et al. Proc. Natl. Acad. Sci. NO: 428) U.S.A. 102(44):16013-8 (2005). 14 HAUS3 ILNAMIAKI SEQ ID NO: Robbins et al. Nat Med. 19(6):747- 429) 52 (2013). 15 LDLR- WRRAPAPGA (SEQ ID Wang et al. J Exp Med. fucosyltransferase NO: 430) and 189(10):1659-68 (1999). PVTWRRAPA (SEQ ID NO: 431) 16 MART2 FLEGNEVGKTY (SEQ ID Kawakami et al. J Immunol. NO: 432) 166(4):2871-7 (2001). 17 MATN KTLTSVFQK (SEQ ID NO: Robbins et al. Nat Med. 19(6):747- 433) 52 (2013). 18 MUM-1 EEKLIVVLF (SEQ ID NO: Coulie et al. Proc. Natl. Acad. Sci. 434) U.S.A. 92(17):7976-80 (1995). 19 MUM-2 SELFRSGLDSY (SEQ ID Chiari et al. Cancer Res. NO: 435)  and 59(22):5785-92 (1999). FRSGLDSYV(SEQ ID NO: 436) 20 MUM-3 EAFIQPITR (SEQ ID NO: Baurain et al. J. Immunol. 437) 164(11):6057-66 (2000). 21 neo-PAP RVIKNSIRLTL (SEQ ID Topalian et al. Cancer Res. NO: 438) 62(19):5505-9 (2002). 22 Myosin class I KINKNPKYK (SEQ ID NO:  Zorn, et al. Eur. J. Immunol. 439) 29(2):592-601 (1999). 23 PPP1R3B YTDFHCQYV (SEQ ID Robbins et al. Nat Med. 19(6):747- NO: 440) 52 (2013). Lu et al. J Immunol. 190(12):6034- 42 (2013). 24 PRDX5 LLLDDLLVSI (SEQ ID Sensi et al. Cancer Res. 65(2):632- NO: 441) 40 (2005). 25 PTPRK PYYFAAELPPRNLPEP Novellino et al. J. Immunol. (SEQ ID NO: 442) 170(12):6363-70 (2003). 26 N-ras ILDTAGREEY (SEQ ID Linard et al. J. Immunol. NO: 443) 168(9):4802-8 (2002). 27 RBAF600 RPHVPESAF (SEQ ID NO: Lennerz et al. Proc. Natl. Acad. Sci. 444) U.S.A. 102(44):16013-8 (2005). 28 SIRT2 KIFSEVTLK (SEQ ID NO: Lennerz et al. Proc. Natl. Acad. Sci. 445) U.S.A. 102(44):16013-8 (2005). 29 SNRPDI SHETVIIEL (SEQ ID NO: Lennerz et al. Proc. Natl. Acad. Sci. 446) U.S.A. 102(44):16013-8 (2005). 30 Triosephosphate GELIGILNAAKVPAD Pieper et al. J Exp Med. 189(5):757- isomerase (SEQ ID NO: 447) 66 (1999). 31 OAI LYSACFWWL (SEQ ID Touloukian et al. J. Immunol. NO: 448) 170(3):1579-85 (2003). 32 RAB38/NY-MEL- VLHWDPETV (SEQ ID Walton et al. J Immimol. 1 NO: 449) 177(11):8212-8 (2006). 33 TRP-I/gp75 MSLQRQFLR (SEQ ID NO:  Toulouldan et al. Cancer Res. 450); 62(18):5144-7 (2002). ISPNSVFSQWRVVCDSLE Robbins et al. J. Immunol. DY (SEQ ID NO: 451); (10):6036-47 (2002). SLPYWNFATG (SEQ ID Osen et al. PLoS One. 5(11):e14137 NO: 452); and (2010). SQWRVVCDSLEDYDT (SEQ ID NO: 453) 34 TRP-2 SVYDFFVWL (SEQ ID Parkhurst et al. Cancer Res. NO: 454); 58(21):4895-901 (1998). TLDSQVMSL (SEQ ID NO: Noppen et al. hit. J. Cancer. 455); 87(2):241-6 (2000). LLGPGRPYR (SEQ ID NO: Wang et al. J. Exp. Med. 456); 1184(6):2207-16 (1996). ANDPIFVVL (SEQ ID NO: Wang et al. J. Immunol 160(2):890- 457); 7(1998). QCTEVRADTRPWSGP Castelli et al. J. Immunol. (SEQ ID NO: 458); and 162(3):1739-48 (1999). ALPYWNFATG (SEQ ID Paschen et al. Clin. Cancer Res. NO: 459) (14):5241-7 (2005). Robbins et al. J. Immunol. 169(10):6036-47 (2002). 35 tyrosinase KCDICTDEY (SEQ ID NO: Kittlesen et al. J. Immunol. 460); 160(5):2099-106 (1998). SSDYVIPIGTY (SEQ ID Kawakami et al. J. Immunol. NO: 461); (12):6985-92 (1998). MLLAVLYCL (SEQ ID Wolfel et al. Eur. J. Immunol. NO: 462); 24(3):759-64 (1994). CLLWSFQTSA (SEQ ID Riley et al. I Immunother. NO: 463); 24(3):212-20 (2001). YMDGTMSQV (SEQ ID Skipper et al. J. Exp. Med. NO: 464); 183(2):527-34 (1996). AFLPWHRLF (SEQ ID NO: Kang et al. J. Immunol. 229); 155(3):1343-8 (1995). IYMDGTADFSF (SEQ ID Dalet et al. Proc. Natl. Acad. Sci. NO: 465); U.S.A. 108(29):E323-31 (2011) QCSGNFMGF (SEQ ID Lennerz et al. Proc. Natl. Acad. Sci. NO: 466); U.S.A. 102(44):16013-8 (2005). TPRLPSSADVEF (SEQ ID Benlalam et al. J. Immunol. NO: 467); 171(11):6283-9 (2003). LPSSADVEF (SEQ ID NO: Morel et al. Int. J. Cancer. 468); 83(6):755-9 (1999). LHHAFVDSIF (SEQ ID Brichard et al. Eur. J. Immunol NO: 469); 26(1):224-30 (1996). SEIWRDIDF (SEQ ID NO:  Topalian et al. J. Exp. Med. 470); (5):1965-71 (1996). QNILLSNAPLGPQFP (SEQ Kobayashi et al. Cancer Res. ID NO: 471); 58(2):296-301 (1998). SYLQDSDPDSFQD (SEQ ID NO: 661); and FLLHHAFVDSIFEQWLQR HRP (SEQ ID NO: 472) 36 Melan-A/MART-1 YTTAEEAAGIGILTVILGV Meng et al. J. Immunother. 23:525- LLLIGCWYCRR (SEQ ID 534(2011) NO: 473) 37 g59100/Pmell7 ALNFPGSQK (SEQ ID NO: El Hage et al. Proc. Natl. Acad. Sci. 474) U.S.A. 105(29):10119-24 (2008). ALNFPGSQK (SEQ ID NO:  Kawashima et al. Hum Immunol. 474) 59(1):1-14 (1998). VYFFLPDHL (SEQ ID NO: Robbins et al. J Immunol. 475) 159(1):303-8 (1997). RTKQLYPEW (SEQ ID Sensi et al. Tissue Antigens. NO: 476) 59(4):273-9 (2002). HTMEVTVYHR (SEQ ID Lennerz et al. Proc Natl Acad Sci U NO: 477) S A. 102(44):16013-8 (2005). SSPGCQPPA (SEQ ID NO: Benlalam et al. I Immunol. 478) 171(11):6283-9 (2003). VPLDCVLYRY (SEQ ID Vigneron et al. Tissue Antigens. NO: 479) 65(2):156-62 (2005). LPHSSSHWL (SEQ ID NO: Castelli et al. J Immunol. 480) 162(3):1739-48 (1999). SNDGPTLI (SEQ ID NO: Touloulcian et al. J Immunol. 481) 164(7):3535-42 (2000). GRAMLGTHTMEVTVY Parkhurst et al. J Immunother. (SEQ ID NO: 482) 27(2):79-91 (2004). WNRQLYPEWTEAQRLD Lapointe et at. J Immunol. (SEQ ID NO: 483) 167(8):4758-64 (2001). TTEWVEITARELPIPEPE Kobayashi et al. Cancer Res. (SEQ ID NO: 484) 61(12):4773-8 (2001). TGRAMLGTHTMEVTVY H(SEQ ID NO: 485) GRAMLGTHTMEVTVY (SEQ ID NO: 482) 38 NY-ESO-1 HLA-A2-restricted peptide Jager et at. Proc. Natl. Acad. Scie. p157-165 (SLLMWITQC U.S.A. 103(39):14453-8 (2006). SEQ ID NO: 230)), HLA- Gnjatic et al. PNAS Cw3-restricted p92-100 September 26, 2000 vol. 97 no. 20 p. (LAMP-FATPM (SEQ ID 10919 NO: 231)) and HLA-Cw6- Jager etal. J Exp Med. 187(2):265- restricted p80-88 70 (1998). (ARGPESRLL (SEQ ID NO: Chen et al. J Immunol. 165(2):948- 232)) 55 (2000). SLLMWITQC (SEQ ID NO: Valmori et al. Cancer Res. 230) 60(16):4499-506 (2000). MLMAQEALAFL (SEQ ID Aarnoudse et al. Int J Cancer. NO: 233) 82(3):442-8 (1999). YLAMPFATPME (SEQ ID Eikawa et al. hit J Cancer. NO: 234) 132(2):345-54 (2013). ASGPGGGAPR (SEQ ID Wang et al. J Immunol. 161(7):3598- NO: 235) 606 (1998). LAAQERRVPR (SEQ ID Matsuzald et at. Cancer Immunol NO: 236) Immunother. 57(8)1185-95 (2008). TVSGNILTIR (SEQ ID NO: Ebert et al. Cancer Res. 69(3):1046- 237) 54 (2009). APRGPHGGAASGL (SEQ Eikawa et al. Int J Cancer. ID NO: 238) 132(2):345-54 (2013). MPFATPMEAEL (SEQ ID Knights et al. Cancer Immunol NO: 239) Immunother. 58(3):325-38 (2009). KEFTVSGNILTI (SEQ ID Jager et al. Cancer Immun. 2:12 NO: 240) (2002). MPFATPMEA (SEQ ID Zeng et al. Proc Natl Acad Sci U S NO: 241) A. 98(7):3964-9 (2001). FATPMEAEL (SEQ ID NO: Mandic et al. J Immunol. 242) 174(3):1751-9 (2005). FATPMEAELAR (SEQ ID Chen et al. Proc Natl Acad Sci U S NO: 243) A. 101(25):9363-8 (2004). LAMPFATPM (SEQ ID Ayyoub et al. Clin Cancer Res. NO: 231) 16(18):4607-15 (2010). ARGPESRLL (SEQ ID NO: Slager et al. J Immunol. 232) 172(8):5095-102 (2004). SLLMWITQCFLPVF (SEQ Mizote et al. Vaccine. 28(32):5338- ID NO: 244) 46 (2010). LLEFYLAMPFATPMEAEL Jager et al. J Exp Med. 191(4):625- -ARRSLAQ (SEQ ID NO: 30 (2000). 245) Zarour et al. Cancer Res. EFYLAMPFATPM (SEQ ID 60(17):4946-52 (2000). NO: 246) Zeng et al. J Immunol. 165(2):1153- PGVLLKEFTVSGNILTIRL 9(2000). -TAADHR (SEQ ID NO: Bioley et al. Clin Cancer Res. 247) 15(13):4467-74 (2009). RLLEFYLAMPFA (SEQ ID Zarour et al. Cancer Res. 62(1):213- NO: 248) 8 (2002). QGAMLAAQERRVPRAAE Hasegawa et al. Clin Cancer Res. -VPR (SEQ ID NO: 249) 12(6):1921-7 (2006). PFATPMEAELARR (SEQ ID NO: 250) PGVLLKEFTVSGNILTIRL T (SEQ ED NO: 251) VLLKEFTVSG (SEQ ID NO: 252) AADHRQLQLSISSCLQQL (SEQ ID NO: 253) LKEFTVSGNILTIRL (SEQ ID NO: 254) PGVILICEFTVSGNILTIRL -TAADHR (SEQ ID NO: 247) LLEFYLAMPFATPMEAEL -ARRSLAQ (SEQ ID NO: 245) KEFTVSGNILT (SEQ ID NO: 255) LLEFYLAMPFATPM (SEQ ID NO: 256) AGATGGRGPRGAGA (SEQ ID NO: 257) 39 BAGE-1 AARAVFLAL (SEQ ID NO: Boel et al. Immunity. 2(2):167- 333) 75 (1995). 40 GAGE-1,2,8 YRPRPRRY (SEQ ID NO: Van den Eynde et al. J Exp Med. 397) 182(3):689-98 (1995). 41 GAGE-3,4,5,6,7 YYWPRPRRY (SEQ ID De Backer etal. Cancer Res. (cutaneous NO: 412) 59(13):3157-65 (1999). melanoma) 42 GnTVf VLPDVFIRC(V) (SEQ ID Guilloux et al. J Exp Med. NO: 486) 183(3):1173-83 (1996). 43 HERV-K-MEL MLAVISCAV (SEQ ID NO: Schiavetti et al. Cancer Res. 309) 62(19):5510-6 (2002). 44 KK-LC-1 RQKRILVNL (SEQ ID NO: Fukuyama et al. Cancer Res. 310) 66(9):4922-8 (2006). 45 KM-HN-1 NYNNFYRFL (SEQ ID NO: Fukuyama et al. Cancer Res. 311) 66(9):4922-8 (2006). EYSICECLICEF (SEQ ID Monji et al. Clin Cancer Res. 10(18 NO: 312) Pt 1):6047-57 (2004). EYLSLSDKI (SEQ ID NO: 313) 46 LAGE-1 MLMAQEALAFL (SEQ ID Aarnoudse et al. Int J Cancer. NO: 233) 82(3):442-8 (1999). SLLMWITQC (SEQ ID NO: Rimoldi et al. J Immunol. 230) 165(12):7253-61 (2000). LAAQERRVPR (SEQ ID Wang et al. J Immunol. 161(7):3598- NO: 236) 606 (1998). ELVRRILSR (SEQ ID NO: Sun et al. Cancer Immunol 314) Immunother. 55(6):644-52 (2006). APRGVRMAV (SEQ ID Stager et al. Cancer Gene Ther. NO: 315) 11(3):227-36 (2004). SLLMWITQCFLPVF (SEQ Zeng et al. Proc Natl Acad Sci U S ID NO: 244) A. 98(7):3964-9 (2001). QGAMLAAQERRVPRAAE Slager et al. J Immunol. VP-R (SEQ ID NO: 249) 172(8):5095-102 (2004). AADHRQLQLSISSCLQQL Jager et al. J Exp Med. 191(4):625- (SEQ ID NO: 253) 30 (2000). CLSRRPW1CRSWSAGSCP Slager et al. J Immunol. G-MPHL (SEQ ID NO: 316) 170(3):1490-7 (2003). ILSRDAAPLPRPG (SEQ ID Wang et al. Immunity. 20(1):107-18 NO: 317) (2004). AGATGGRGPRGAGA Hasegawa et al. Clin Cancer Res. (SEQ ID NO: 257) 12(6):1921-7 (2006). 47 LY6K RYCNLEGPPI (SEQ ID Suda et al. Cancer Sci. 98(11):1803- NO: 487) 8 (2007). KWTEPYCVIAAVKIFPRF Tomita et al. Oncoimmunology. FMV-AKQ (SEQ ID NO: 3:e28100 (2014). 488) KCCICIRYCNLEGPPINSSV F (SEQ ID NO: 489) 48 MAGE-A1 EADPTGHSY (SEQ ID NO: Traversari et al. J Exp Med. 334) 176(5):1453-7 (1992). KVLEYVHCV (SEQ ID NO: Ottaviani et al. Cancer Immunol 335) Immunother. 54(12):1214-20 (2005). SLFRAVITK (SEQ ID NO: Pascolo et al. Cancer Res. 336) 61(10):4072-7 (2001). EVYDGREHSA (SEQ ID Chaux et al. J Immunol. NO: 337) 163(5):2928-36 (1999). RVRFFFPSL (SEQ ID NO: Luiten et al. Tissue Antigens. 338) 55(2):149-52 (2000). EADPTGHSY (SEQ ID NO:  Luiten et al. Tissue Antigens. 334) 56(1):77-81 (2000). REPVTKAEML (SEQ ID Tanzarella et al. Cancer Res. NO: 339) 59(11):2668-74 (1999). KEADPTGHSY (SEQ ID Stroobant et al. Eur J Immunol. NO: 340) 42(6):1417-28 (2012). DPARYEFLW (SEQ ID Corbiere et al. Tissue Antigens. NO: 341) 63(5):453-7 (2004). ITKKVADLVGF (SEQ ID Goodyear et al. Cancer Immunol NO: 342) Immunother. 60(12):1751-61 (2011). SAFPTITNF (SEQ ID NO: van der Bruggen et al. Eur J 343) Immunol24(9):2134-40 (1994).  SAYGEPRKL (SEQ ID NO: Wang et al. Cancer Immunol 344) Immunother. 56(6):807-18 (2007). RVRFFFPSL (SEQ ID NO: Chaux et al. J Exp Med. 189(5):767- 338) 78 (1999). TSCILESLFRAVITK (SEQ Chaux et al. Eur J Immunol. ID NO: 345) 31(6):1910-6 (2001). PRALAETSYVKVLEY (SEQ ID NO: 346) FLLIKYRAREPVTKAE (SEQ ID NO: 347) EYVIKVSARVRF (SEQ ID NO: 348) 49 MAGE-A6 MVKISGGPR (SEQ ID NO: Zorn et al. Eur J Immunol. 398) 29(2):602-7 (1999). EVDPIGHVY (SEQ ID NO: Benlalam et al. J Immunol. 399) 171(11):6283-9 (2003). REPVTKAEML (SEQ ID Tanzarella et al. Cancer Res. NO: 339) 59(11):2668-74 (1999). EGDCAPEEK (SEQ ID NO: Breckpot et al. J Immunol. 351) 172(4):2232-7 (2004). ISGGPRISY (SEQ ID NO: Vantomme et al. Cancer Immun. 400) 3:17 (2003). LLKYRAREPVTKAE (SEQ Chaux et al. J Exp Med. 189(5):767- ID NO: 352) 78 (1999). 50 MAGE-A10 GLYDGMEHL (SEQ ID Huang et al. J Immunol. NO: 490) 162(11):6849-54 (1999). DPARYEFLW (SEQ ID Chaux et al. J Immunol. NO: 341) 163(5):2928-36 (1999). 51 MAGE-Al2 FLWGPRALV (SEQ ID van der Bruggen et al. Eur J NO: 491) Immunol. 24(12):3038-43 (1994). VRIGHLYIL (SEQ ID NO: Heidecker et al. J Immunol. 492) 164(11):6041-5 (2000). EGDCAPEEK (SEQ ID NO: Panelli et al. J Immunol. 351) 164(8):4382-92 (2000). REPFTICAEMLGSVIR Breckpot et al. J Immunol. (SEQ ID NO: 493) 172(4):2232-7 (2004). AELVHFLLLKYRAR (SEQ Wang et al. Cancer Immunol ID NO: 494) Immunother. 56(6):807-18 (2007). Chaux et al. J Exp Med. 189(5):767- 78(1999). 52 MAGE-C2 LLFGLALIEV (SEQ ID Ma et al. Int .1. Cancer. 109(5):698- NO: 495) 702 (2004). ALKDVEERV (SEQ ID Godelaine et al. Cancer Immunol NO: 496) Immunother. 56(6):753-9 (2007). SESIKKKVL (SEQ ID NO: Ma et al. Int J Cancer. 129(10):2427- 497) 34 (2011). ASSTLYLVF (SEQ ID NO: Wen et al. Cancer Sci. 102(8):1455- 498) 61 (2011). SSTLYLVFSPSSFST (SEQ ID NO: 499) 53 NA88-A QGQHFLQKV (SEQ ID Moreau-Aubry et al. J Exp Med. NO: 500) 191(9):1617-24 (2000). 54 Sp17 ILDSSEEDK (SEQ ID NO: Chiriva-Internati et al. Int J Cancer. 299) 107(5):863-5 (2003). 55 SSX-2 KASEKIFYV (SEQ ID NO: Ayyoub et al. J Immunol. 353) 168(4):1717-22 (2002). EKIQKAFDDIAKYFSK Ayyoub et al. J Immunol. (SEQ ID NO: 354) 172(11):7206-11 (2004). FGRLQGISPKI SEQ ID Neumann et al. Cancer Immunol NO: 355) Immunother. 60(9):1333-46 (2011). WEKMKASEKIFYVYMKR Ayyoub et al. Clin Immunol. K (SEQ ID NO: 356) 114(1):70-8 (2005). KIFYVYMKRKYEAMT Neumann et al. Int J Cancer. (SEQ ID NO: 357) 112(4):661-8 (2004). KIFYVYMKRKYEAM Ayyoub et al. J Clin Invest. (SEQ ID NO: 358) 113(8):1225-33 (2004). 56 SSX-4 INKTSGPKRGKHAWTHR Ayyoub et al. J Immunol. LRE (SEQ ID NO: 322) 174(8):5092-9 (2005). YFSKKEWEKMKSSEKIV Valmori et al. Clin Cancer Res. YVY (SEQ ID NO: 323) 12(2):398-404 (2006). MKLNYEVMTKLGFKVTL PPF (SEQ ID NO: 324) KHAWTHRLRERKQLVV YEEI (SEQ ID NO: 325) LGFKVTLPPFMRSKRAA DFH (SEQ ID NO: 326) KSSEKIVYVYMICLNYEV MTK (SEQ ID NO: 327) KHAWTHRLRERKQLVV YEEI (SEQ ID NO: 325) 57 TRAG-3 CEFHACWPAFTVLGE Janjic et al. J Immunol. 177(4):2717- (SEQ ID NO: 359) 27 (2006). 58 TRP2-INT2g EVISCKLIKR (SEQ ID NO: Lupetti et al. J Exp Med. 501) 188(6):1005-16 (1998). 59 pgk Morgan et al., J. Immunol. 171:3287-3295 (2003)

TABLE 14  Squamous cell carcinoma Tumor- Reported  associated immunogenic No. antigen epitopes Sources 1 CASP-8 FPSDSWCYF (SEQ ID Mandruzzato et al. J. Exp. Med. NO: 502) 186(5):785-93 (1997). 2 p53 VVPCEPPEV (SEQ ID Ito et al. Int. J. Cancer. NO: 276) 120(12):2618-24 (2007). 3 SAGE LYATVIHDI (SEQ ID Miyahara et al. Clin Cancer Res. NO: 503) 11(15):5581-9 (2005).

TABLE 15 Chronic myeloid leukemia Tumor- associated Reported immunogenic No.  antigen epitopes Sources 1 BCR-ABL SSKALQRPV(SEQ ID NO: Yotnda et al. J. Clin. Invest. 504); 101(10):2290-6 (1998). GFKQSSKAL(SEQ ID NO: Bosch et al. Blood. 88(9):3522-7 505); (1996). ATGFKQSSICALQRPVAS Makita et al. Leukemia. (SEQ ID NO: 506); and 16(12):2400-7 (2002). ATGFKQSSICALQRPVAS (SEQ ID NO: 506) 2 dek-can TMKQICKKEIRRLHQY Makita et al. Leukemia. (SEQ ID NO: 507) 16(12):2400-7 (2002). 3 EFTUD2 KILDAVVAQK (SEQ ID Lennerz et al. Proc. Natl. Acad. NO: 508) Sci. U.S.A. 102(44):16013-8 (2005). 4 GAGE-3,4,5,6,7 YYWPRPRRY (SEQ ID De Backer et al. Cancer Res. NO: 412) 59(13):3157-65 (1999).

TABLE 16 Acute lymphoblastic leukemia Tumor- associated Reported immunogenic No.  antigen epitopes Sources 1 ETV6-AML1 RIAECILGM (SEQ ID NO: Yotnda et al. J. Clin. Invest. 509) and (2):455-62 (1998). IGRIAECILGMNPSR Yun et al. Tissue Antigens. (SEQ ID NO: 510) 54(2):153-61 (1999). 2 GAGE-3,4,5,6,7 YYWPRPRRY(SEQ ID De Backer et al. Cancer Res. NO: 412) 59(13):3157-65 (1999).

TABLE 17 Acute myelogenous leukemia Tumor- associated Reported immunogenic No.  antigen epitopes Sources 1 FLT3-ITD YVDFREYEYY (SEQ ID Graf et al. Blood. 109(7):2985-8 NO: 511) (2007). 2 Cyclin-Al FLDRFLSCM (SEQ ID Ochsenreither et al. Blood. NO: 512) and 119(23):5492-501 (2012). SLIAAAAFCLA (SEQ ID NO: 513) 3 GAGE-3,4,5,6,7 YYWPRPRRY (SEQ ID De Backer et al. Cancer Res. NO: 412) 59(13):3157-65 (1999).

TABLE 18 Chronic lymphocytic leukemia Tumor- associated Reported immunogenic No.  antigen epitopes Sources Tumor- associated Reported immunogenic No.  antigen epitopes Sources 1 FNDC3B VVMSWAPPV (SEQ ID Rajasagi et al. Blood. 124(3):453- NO: 514) 62 (2014). 2 GAGE-3,4,5,6,7 YYWPRPRRY (SEQ ID De Backer et al. Cancer Res. NO: 412) 59(13):3157-65 (1999).

TABLE 19 Promyelocytic leukemia Tumor- associated Reported immunogenic No.  antigen epitopes Sources 1 pml-RARalpha NSNHVASGAGEAMETQS Gambacorti-Passerini et al. Blood. SSSEEIV (SEQ ID NO: 515) 81(5):1369-75 (1993). 2 GAGE-3,4,5,6,7 YYWPRPRRY (SEQ ID De Backer et al. Cancer Res. NO: 412) 59(13):3157-65 (1999).

TABLE 20 Multiple myeloma Tumor- associated Reported immunogenic No.  antigen epitopes Sources 1 MAGE-C1 ILFGISLREV (SEQ ID NO: Anderson et al. Cancer Immunol 516) Immunother. 60(7):985-97 (2011). KVVEFLAML (SEQ ID Nuber et al. Proc Natl Acad Sci U S NO: 517) A. 107(34):15187-92 (2010). SSALLSIFQSSPE (SEQ ID NO: 518) SFSYTLLSL (SEQ ID NO: 519) VSSFFSYTL (SEQ ID NO: 520) 2 NY-ESO-1 HLA-A2-restricted peptide Jager et al. Proc. Natl. Acad. Scie. p157-165 (SLLMWITQC U.S.A. 103(39):14453-8 (2006). (SEQ ID NO: 230)), HLA- Gnjatic et al. PNAS Cw3-restricted p92-100 September 26,2000 vol. 97 no. 20 p. LAMP-FATPM (SEQ ID 10919 NO: 231)) and HLA-Cw6- Jager et al. J Exp Med. 187(2):265- restricted p80-88 70 (1998). (ARGPESRLL (SEQ ID NO: Chen et al. J Immunol. 165(2):948- 232)) 55 (2000). SLLMWITQC (SEQ ID NO: Valmori et al. Cancer Res. 230) 60(16):4499-506 (2000). MLMAQEALAFL (SEQ ID Aamoudse et al. Int J Cancer. NO: 233) 82(3):442-8 (1999). YLAMPFATPME (SEQ ID Eikawa et al. Int J Cancer. NO: 234) 132(2):345-54 (2013). ASGPGGGAPR (SEQ ID Wang et al. J Immunol. 161(7):3598- NO: 235) 606 (1998). LAAQERRVPR (SEQ ID Matsuzaki et al. Cancer Immunol NO: 236) Immunother. 57(8)1185-95 (2008). TVSGNILTIR (SEQ ID NO: Ebert et al. Cancer Res. 69(3):1046- 237) 54 (2009). APRGPHGGAASGL (SEQ Eikawa et al. Int J Cancer. ID NO: 238) 132(2):345-54 (2013). MPFATPMEAEL (SEQ ID Knights et al. Cancer Immunol NO: 239) Immunother. 58(3):325-38 (2009). KEFTVSGNILTI (SEQ ID Jager et al. Cancer Immun. 2:12 NO: 240) (2002). MPFATPMEA (SEQ ID Zeng et al. Proc Natl Acad Sci U S NO: 241) A. 98(7):3964-9 (2001). FATPMEAEL (SEQ ID NO: Mandic et al. J Immunol. 242) 174(3):1751-9 (2005). FATPMEAELAR (SEQ ID Chen et al. Proc Natl Acad Sci U S NO: 243) A. 101(25):9363-8 (2004). LAMPFATPM (SEQ ID Ayyoub et al. Clin Cancer Res. NO: 231) 16(18):4607-15 (2010). ARGPESRLL (SEQ ID NO: Slager et al. J Immunol. 232) 172(8):5095-102 (2004). SLLMWITQCFLPVF (SEQ Mizote et al. Vaccine. 28(32):5338- ID NO: 244) 46 (2010). LLEFYLAMPFATPMEAEL Jager et al. J Exp Med. 191(4):625- -ARRSLAQ (SEQ ID NO: 30 (2000). 245) Zarour et al. Cancer Res. EFYLAMPFATPM (SEQ ID 60(17):4946-52 (2000). NO: 246) Zeng et al. J Immunol. 165(2):1153- PGVLLKEFTVSGNILTIRL 9(2000). -TAADHR (SEQ ID NO: Bioley et al. Clin Cancer Res. 247) 15(13):4467-74 (2009). RLLEFYLAMPFA (SEQ ID Zarour et al. Cancer Res. 62(1):213- NO: 248) 8 (2002). QGAMLAAQERRVPRAAE Hasegawa et al. Clin Cancer Res. -VPR (SEQ ID NO: 249) 12(6):1921-7 (2006). PFATPMEAELARR SEQ ID NO: 250) PGVLLICEFTVSGNILTIRL T (SEQ ID NO: 251) VLLKEFTVSG (SEQ ID NO: 252) AADHRQLQLSISSCLQQL (SEQ ID NO: 253) LKEFTVSGNILTIRL (SEQ ID NO: 254) PGVLLICEFTVSGNILTIRL -TAADHR (SEQ ID NO: 247) LLEFYLAMPFATPMEAEL -ARRSLAQ (SEQ ID NO: 245) KEFTVSGNILT (SEQ ID NO: 255) LLEFYLAMPFATPM (SEQ ID NO: 256) AGATGGRGPRGAGA (SEQ ID NO: 257) 3 LAGE-1 MLMAQEALAFL (SEQ ID Aamoudse et al. Int J Cancer. NO: 233) 82(3):442-8 (199) SLMMWITQC (SEQ ID NO: Rimoldi et al. J Immunol. 230) 165(12):7253-61 (2000). LAAQERRVPR (SEQ ID Wang et al. J Immunol. 161(7):3598- NO: 236) 606 (1998). ELVRRILSR (SEQ ID NO: Sun et al. Cancer Immunol 314) Immunother. 55(6):644-52 (2006). APRGVRMAV (SEQ ID Slager et al. Cancer Gene Ther. NO: 315) 11(3):227-36 (2004). SLLMWITQCFLPVF (SEQ Zeng et al. Proc Natl Acad Sci U S ID NO: 244) A. 98(7):3964-9 (2001). QGAMLAAQERRVPRAAE Slager et al. J Immunol. VP-R (SEQ ID NO: 249) 172(8):5095-102 (2004). AADHRQLQLSISSCLQQL Jager et al. J Exp Med. 191(4):625- (SEQ ID NO: 253) 30 (2000). CLSRRPWKRSWSAGSCP Slager et al. J Immunol. G-MPHL (SEQ ID NO: 316) 170(3):1490-7 (2003). ILSRDAAPLPRPG (SEQ ID Wang etal. Immunity. 20(1):107-18 NO: 317) (2004). AGATGGRGPRGAGA Hasegawa et al. Clin Cancer Res. SEQ ID NO: 257) 12(6):1921-7 (2006). 4 HERV-K-MEL MLAVISCAV (SEQ ID NO: Schiavetti et al. Cancer Res. 309) 62(19):5510-6 (2002). 5 KK-LC-1 RQKRILVNL (SEQ ID NO: Fukuyama et al. Cancer Res. 310) 66(9):4922-8 (2006). 6 KM-HN-1 NYNNFYRFL (SEQ ID NO: Fukuyama et al. Cancer Res. 311) 66(9):4922-8 (2006). EYSKECLKEF (SEQ ID Monji et al. Clin Cancer Res. 10(18 NO: 312) Pt 1):6047-57 (2004). EYLSLSDKI (SEQ ID NO: 313) 7 Sp17 ILDSSEEDK (SEQ ID NO: Chiriva-Internati et al. Int J Cancer. 299) 107(5):863-5 (2003).

TABLE 21 B-cell lymphoma Tumor- Reported  associated immunogenic No.  antigen epitopes Sources 1 KPLFRRMSSLELVIA Vauchy et al. Int J Cancer. D393-CD20 (SEQ ID 137(1):116-26 (2015).  NO: 521)

TABLE 22 Bladder carcinoma Tumor- associated Reported immunogenic No.  antigen epitopes Sources 1 BAGE-1 AARAVFLAL (SEQ ID NO: Boel et al. Immunity. 2(2):167- 333)  75 (1995). 2 GAGE-1,2,8 YRPRPRRY (SEQ ID NO: Van den Eynde et al. J Exp Med. 397) 182(3):689-98 (1995). 3 GAGE-3,4,5,6,7 YYWPRPRRY (SEQ ID De Backer et al. Cancer Res. NO: 412) 59(13):3157-65 (1999). 4 MAGE-A4 EVDPASNTY (SEQ ID NO: Kobayashi et al. Tissue Antigens. (transitional cell  318) 62(5):426-32 (2003). carcinoma of GVYDGREHTV (SEQ ID Duffour et al. Eur J Immunol. urinary bladder) NO: 319) 29(10):3329-37 (1999). NYKRCFPVI (SEQ ID NO: Miyahara et al. Clin Cancer Res. 320) 11(15):5581-9 (2005). SESLICMIF (SEQ ID NO: Ottaviani et al. Cancer Immunol 321) Immunother. 55(7):867-72 (2006). Zhang et al. Tissue Antigens. 60(5):365-71 (2002). 5 MAGE-A6 MVKISGGPR (SEQ ID NO: Zorn et al. Eur J Immunol. 398) 29(2):602-7 (1999). EVDPIGHVY (SEQ ID NO: Benlalam et al. J Immunol. 399) 171(11):6283-9 (2003). REPVTKAEML (SEQ ID Tanzarella et al. Cancer Res. NO: 339) 59(11):2668-74 (1999). EGDCAPEEK (SEQ ID NO: Breckpot et al. J Immunol. 351) 172(4):2232-7 (2004). ISGGPRISY (SEQ ID NO: Vantomme et al. Cancer Immun. 400) 3:17 (2003). LLKYRAREPVTKAE SEQ Chaux et al. J Exp Med. 189(5):767- ID NO: 352) 78 (1999). 6 SAGE LYATVIHDI (SEQ ID NO: Miyahara et al. Clin Cancer Res. 503) 11(15):5581-9 (2005). 7 NY-ESO-1 HLA-A2-restricted peptide Jager et al. Proc. Natl. Acad. Scie. p157-165 (SLLMWITQC U.S.A. 103(39):14453-8 (2006). (SEQ ID NO: 230)), HLA- Cw3-restricted p92-100 Gnjatic et al. PNAS (LAMP-FATPM (SEQ ID September 26, 2000 vol. 97 no. 20 p. NO: 231)) and HLA-Cw6- 10919 restricted p80-88 Jager et al. J Exp Med. 187(2):265- (ARGPESRLL (SEQ ID NO: 70 (1998). 232)) Chen et al. J Immunol. 165(2):948- SLLMWITQC (SEQ ID NO: 55 (2000). 230) Valmori et al. Cancer Res. 60(16):4499-506 (2000). MLMAQEALAFL (SEQ ID Aarnoudse et al. Int J Cancer. NO: 233) 82(3):442-8 (1999). YLAMPFATPME (SEQ ID Eikawa et al. Int J Cancer. NO: 234) 132(2):345-54 (2013). ASGPGGGAPR (SEQ ID Wang et al. J Immunol. 161(7):3598- NO: 235) 606 (1998). LAAQERRVPR (SEQ ID Matusuzki et al. Cancer Immunol NO: 236) Immunother. 57(8)1185-95 (2008). TVSGNILTIR (SEQ ID NO: Ebert et al. Cancer Res. 69(3):1046- 237) 54 (2009). APRGPHGGAASGL (SEQ Eikawa et al. Int J Cancer. ID NO: 238) 132(2):345-54 (2013). MPFATPMEAEL (SEQ ID Knights et al. Cancer Immunol NO: 239) Immunother. 58(3):325-38 (2009). KEFTVSGNILTI (SEQ ID Jager et al. Cancer Immun. 2:12 NO: 240) (2002). MPFATPMEA (SEQ ID Zeng et al. Proc Natl Acad Sci U S NO: 241) A. 98(7):3964-9 (2001). FATPMEAEL (SEQ ID NO: Mandic et al. J Immunol. 242) 174(3):1751-9 (2005). FATPMEAELAR (SEQ ID Chen et al. Proc Natl Acad Sci U S NO: 243) A. 101(25):9363-8 (2004). LAMPFATPM (SEQ ID Ayyoub et al. Clin Cancer Res. NO: 231) 16(18):4607-15 (2010). ARGPESRLL (SEQ ID NO: Slager et al. J Immunol 232) 172(8):5095-102 (2004). SLLMWITQCFLPVF (SEQ Mizote et al. Vaccine. 28(32):5338- ID NO: 244) 46 (2010). LLEFYLAMPFATPMEAEL Jager et al. J Exp Med. 191(4):625- -ARRSLAQ (SEQ ID NO: 30 (2000). 245) Zarour et al. Cancer Res. EFYLAMPFATPM (SEQ ID 60(17):4946-52 (2000). NO: 246) Zeng et al. J Immunol. 165(2):1153- PGVLLKEFTVSGNILTIRL 9(2000). -TAADHR (SEQ ID NO: Bioley et al. Clin Cancer Res. 247) 15(13):4467-74 (2009). RLLEFYLAMPFA SEQ ID Zarour et al. Cancer Res. 62(1):213- NO: 248) 8 (2002). QGAMLAAQERRVPRAAE Hasegawa et al. Clin Cancer Res. -VPR (SEQ ID NO: 249) 12(6):1921-7 (2006). PFATPMEAELARR (SEQ ID NO: 250) VLLKEFTVSG (SEQ ID NO: 252) AADHRQLQLSISSCLQQL (SEQ ID NO: 253) LKEFTVSGNILTIRL (SEQ ID NO: 254) PGVLLKEFTVSGNILTIRL -TAADHR (SEQ ID NO: 247) LLEFYLAMPFATPMEAEL -ARRSLAQ (SEQ ID NO: 245) KEFTVSGNILT (SEQ ID NO: 255) LLEFYLAMPFATPM (SEQ ID NO: 256) AGATGGRGPRGAGA (SEQ ID NO: 257) 8 LAGE-1 MLMAQEALAFL (SEQ ID Aamoudse et al. Int J Cancer. NO: 233) 82(3):442-8 (1999). SLLMWITQC (SEQ ID NO: Rimoldi et al. J Immunol. 230) 165(12):7253-61 (2000). LAAQERRVPR (SEQ ID Wang et al. J Immunol. 161(7):3598- NO: 236) 606 (1998). ELVRRILSR (SEQ ID NO: Sun et al. Cancer Immunol 314) Immunother. 55(6):644-52 (2006). APRGVRMAV (SEQ ID Slager et al. Cancer Gene Ther. NO: 315) 11(3):227-36 (2004). SLLMWITQCFLPVF (SEQ Zeng et al. Proc Natl Acad Sci U S ID NO: 244) A. 98(7):3964-9 (2001). QGAMLAAQERRVPRAAE Slager et al. J Immunol. VP-R (SEQ ID NO: 249) 172(8):5095-102 (2004). AADHRQLQLSISSCLQQL Jager etal. J Exp Med. 191(4):625- (SEQ ID NO: 253) 30 (2000). CLSRRPWICRSWSAGSCP Slager et al. J Immunol. G-MPHL (SEQ ID NO: 316) 170(3):1490-7 (2003). ILSRDAAPLPRPG (SEQ ID Wang et al. Immunity. 20(1):107-18 NO: 317) (2004). AGATGGRGPRGAGA Hasegawa et al. Clin Cancer Res. (SEQ ID NO: 257) 12(6):1921-7 (2006). 9 HERV-K-MEL MLAVISCAV (SEQ ID NO: Schiavetti et al. Cancer Res. 309) 62(19):5510-6 (2002). 10 KK-LC-1 RQKRILVNL (SEQ ID NO: Fukuyama et al. Cancer Res. 310) 66(9):4922-8 (2006). No. Tumor- Reported immunogenic Sources associated epitopes antigen 11 KM-11N-1 NYNNFYRFL (SEQ ID NO: Fukuyama et al. Cancer Res. 311) 66(9):4922-8 (2006). EYSKECLICEF (SEQ ID Monji et al. Clin Cancer Res. 10(18 NO: 312) Pt 1):6047-57 (2004). EYLSLSDKI (SEQ ID NO: 313) 12 SP17 ILDSSEEDK (SEQ ID NO: Chiriva-Internati et al. Int J Cancer. 299) 107(5):863-5 (2003).

TABLE 23 Head and neck cancer Tumor- associated Reported immunogenic No.  antigen epitopes Sources 1 BAGE-1 (head and AARAVFLAL (SEQ ID NO: Boel et al. Immunity. 2(2):167- neck squamous cell 333) 75 (1995). carcinoma) 2 GAGE-1,2,8 YRPRPRRY (SEQ ID NO: Van den Eynde et al. I Exp Med. 397) 182(3):689-98 (1995). 3 GAGE-3,4,5,6,7 YYWPRPRRY (SEQ ID De Backer et al. Cancer Res. NO: 412) 59(13):3157-65 (1999). 4 LY6K RYCNLEGPPI (SEQ ID Suda et al. Cancer Sci. 98(11):1803- NO: 487) 8 (2007). KWTEPYCVIAAVKIFPRF Tomita et al. Oncoimmunology. FMV-AKQ (SEQ ID NO: 3:e28100 (2014). 488) KCCKIRYCNLEGPPINSSV F (SEQ ID NO: 489) 5 MAGE-A3 (head EVDPIGHLY (SEQ ID NO: Gaugler et al. J Exp Med. and neck squamous 662) 179(3):921-30 (1994). cell carcinoma) FLWGPRALV (SEQ ID van der Bruggen et al. Eur J NO: 491) Immunol. 24(12):3038-43 (1994). KVAELVHFL (SEQ ID NO: Kawashima et al. Hum Immunol. 663) 59(1):1-14 (1998). TFPDLESEF (SEQ ID NO: Oiso et al. Int J Cancer. 81(3):387- 664) 94 (1999). VAELVHFLL (SEQ ID NO: Miyagawa et al. Oncology. 70(1):54- 665) 62 (2006). MEVDPIGHLY (SEQ ID Bilsborough et al. Tissue Antigens. NO: 666) 60(1):16-24 (2002). EVDPIGHLY (SEQ ID NO: Schultz et al. Tissue Antigens. 662) 57(2):103-9 (2001). REPVTKAEML (SEQ ID Tanzarella et al. Cancer Res. NO: 339) 59(11):2668-74 (1999). AELVHFLLL (SEQ ID NO: Schultz et at. J Exp Med. 667) 195(4):391-9 (2002). MEVDPIGHLY (SEQ ID Herman et al. Immunogenetics. NO: 666) 43(6):377-83 (1996). WQYFFPVIF (SEQ ID NO: Russo et al. Proc Natl Acad Sci U S 668) A. 97(5):2185-90 (2000). EGDCAPEEK (SEQ ID NO: Breckpot et al. J Immunol. 351) 172(4):2232-7 (2004). KKLLTQHFVQENYLEY Schultz et al. Cancer Res. (SEQ ID NO: 669) 60(22):6272-5 (2000). RKVAELVHFLLLKYR Cesson et al. Cancer Immunol (SEQ ID NO: 670) Immunother. 60(1):23-35 (2011). KKLLTQHFVQENYLEY Schultz et al. J Immunol. (SEQ ID NO: 669) 172(2):1304-10 (2004). ACYEFLWGPRALVETS Zhang et al. J Immunol. 171(1):219- (SEQ ID NO: 671) 25 (2003). RKVAELVHFLLLKYR Cesson et al. Cancer Immunol (SEQ ID NO: 670) Immunother. 60(1):23-35 (2010). VIFSKASSSLQL (SEQ ID Kobayashi et al. Cancer Res. NO: 672) 61(12):4773-8 (2001). VFGIELMEVDPIGHL Cesson et al. Cancer Immunol (SEQ ID NO: 673) Immunother. 60(1):23-35 (2011). GDNQIMPKAGLLIIV Consogno et al. Blood. 101(3):1038- (SEQ ID NO: 674) 44 (2003). TSYVKVLIMMVKISG Manici et al. J Exp Med. 189(5):871- (SEQ ID NO: 675) 6 (1999). RKVAELVHFLLLKYRA Chaux et al. J Exp Med. 189(5):767- (SEQ ID NO: 676) 78 (1999). FLLLKYRAREPVTKAE (SEQ ID NO: 347) 6 MAGE-A6 MVIUSGGPR (SEQ ID NO: Zorn et al. Eur J Immunol. 398) 29(2):602-7 (1999). EVDPIGHVY (SEQ ID NO: Benlalam et al. J Immunol. 399) 171(11):6283-9 (2003). REPVTKAEML (SEQ ID Tanzarella et al. Cancer Res. NO: 339) 59(11):2668-74 (1999). EGDCAPEEK (SEQ ID NO: Breckpot et al. J Immunol. 351) 172(4):2232-7 (2004). ISGGPRISY (SEQ ID NO: Vantomme et al. Cancer Immun. 400) 3:17 (2003). LLKYRAREPVTKAE (SEQ Chaux et al. J Exp Med. 189(5):767- ID NO: 352) 78 (1999). 7 SAGE LYATVIHDI (SEQ ID NO: Miyahara et al. Clin Cancer Res. 503) 11(15):5581-9 (2005).

TABLE 24 Esophageal cancer Tumor- associated Reported immunogenic No.  antigen epitopes Sources 1 GAGE-3,4,5,6,7 YYWPRPRRY (SEQ ID De Backer et al. Cancer Res. (Esophageal NO: 412) 59(13):3157-65 (1999). squamous cell carcinoma and esophageal adenocarcinoma) 2 MAGE-A2 YLQLVFGIEV (SEQ ID ICawashima et al. Hum Immunol. NO: 349) 59(1):1-14 (1998). EYLQLVFGI (SEQ ID NO: Tahara et al. Clin Cancer Res. 350) 5(8):2236-41 (1999). REPVTKAEML (SEQ ID Tanzarella et al. Cancer Res. NO: 339) 59(11):2668-74 (1999). EGDCAPEEK (SEQ ID NO: Breckpot et al. J Immunol. 351) 172(4):2232-7 (2004). LLKYRAREPVTKAE (SEQ Chaux et al. J Exp Med. 189(5):767- ID NO: 352) 78 (1999). 3 MAGE-A6 MVKISGGPR (SEQ ID NO: Zorn et al. Eur J Immunol. 398) 29(2):602-7 (1999). EVDPIGHVY (SEQ ID NO: Benlalam et al. J Immunol. 399) 171(11):6283-9 (2003). REPVTKAEML (SEQ ID Tanzarella et al. Cancer Res. NO: 339) 59(11):2668-74 (1999). EGDCAPEEK (SEQ ID NO: Breckpot et al. J Immunol. 351) 172(4):2232-7 (2004). ISGGPRISY (SEQ ID NO: Vantommeet al. Cancer Immun. 400) 3:17 (2003). LLKYRAREPVTKAE (SEQ Chaux et al. J Exp Med. 189(5):767- ID NO: 352) 78 (1999). 4 NY-ESO-1 HLA-A2-restricted peptide Jager et al. Proc. Natl. Acad. Scie. p157-165 (SLLMWITQC U.S.A. 103(39):14453-8 (2006). (SEQ ID NO: 230)), HLA- Gnjatic et al. PNAS Cw3-restricted p92-100 September 26, 2000 vol. 97 no. 20 p. (LAMP-FATPM (SEQ ID 10919 NO: 231)) and HLA-Cw6- Jager et al. J Exp Med. 187(2):265- restricted p80-88 70 (1998). (ARGPESRLL (SEQ ID NO: Chen et al. J Immunol. 165(2):948- 232)) 55 (2000). SLLMWITQC (SEQ ID NO: Valmori et al. Cancer Res. 230) 60(16):4499-506 (2000). MLMAQEALAFL (SEQ ID Aamoudse et al. Int. J Cancer. NO: 233) 82(3):442-8 (1999). YLAMPFATPME (SEQ ID Eikawa et al. Int J Cancer. NO: 234) 132(2):345-54 (2013). ASGPGGGAPR (SEQ ID Wang et al. J Immunol 161(7):3598- NO: 235) 606 (1998). LAAQERRVPR (SEQ ID Matsuzaki et al. Cancer Immunol NO: 236) Immunother. 57(8)1185-95 (2008). TVSGNILTIR (SEQ ID NO: Ebert et al. Cancer Res. 69(3):1046- 237) 54 (2009). APRGPHGGAASGL (SEQ Eikawa et al. Int J Cancer. ID NO: 238) 132(2):345-54 (2013). MPFATPMEAEL (SEQ ID Knights et al. Cancer Immunol NO: 239) Immunother. 58(3):325-38 (2009). KEFTVSGNILTI (SEQ ID Jager et al. Cancer Immun. 2:12 NO: 240) (2002). MPFATPMEA (SEQ ID Zeng et al. Proc Natl Acad Sci U S NO: 241) A. 98(7):3964-9 (2001). FATPMEAEL (SEQ ID NO: Mandic et al. J Immunol. 242) 174(3):1751-9 (2005). FATPMEAELAR (SEQ ID Chen et al. Proc Nati Acad Sci U S NO: 243) A. 101(25):9363-8 (2004). LAMPFATPM (SEQ ID Ayyoub et al. Clin Cancer Res. NO: 231) 16(18):4607-15 (2010). ARGPESRLL (SEQ ID NO:  Slager et al. J Immunol. 232) 172(8):5095-102 (2004). SLLMWITQCFLPVF (SEQ Mizote et al. Vaccine. 28(32):5338- ID NO: 244) 46 (2010). LLEFYLAMPFATPMEAEL Jager et al. J Exp Med. 191(4):625- -ARRSLAQ (SEQ ID NO: 30 (2000). 245) Zarour et al. Cancer Res. EFYLAMPFATPM (SEQ ID 60(17):4946-52 (2000). NO: 246) Zeng et al. J Immunol. 165(2):1153- PGVLLKEFTVSGNILTIRL 9(2000). -TAADHR (SEQ ID NO: Bioley et al. Clin Cancer Res. 247) 15(13):4467-74 (2009). RLLEFYLAMPFA (SEQ ID Zarour et al. Cancer Res. 62(1):213- NO: 248) 8 (2002). QGAMLAAQERRVPRAAE Hasegawa et al. Clin Cancer Res. -VPR (SEQ ID NO: 249) 12(6):1921-7 (2006). PFATPMEAELARR (SEQ ID NO: 250) PGVLLKEFTVSGNILTIRL T (SEQ ID NO: 251) VLLKEFTVSG (SEQ ID NO: 252) AADHRQLQLSISSCLQQL (SEQ ID NO: 253) LKEFTVSGNILTIRL (SEQ ID NO: 254) PGVLLKEFTVSGNILTIRL -TAADHR (SEQ ID NO: 247) LLEFYLAMPFATPMEAEL -ARRSLAQ (SEQ ID NO: 245) KEFTVSGNILT (SEQ ID NO: 255) LLEFYLAMPFATPM (SEQ ID NO: 256) AGATGGRGPRGAGA (SEQ ID NO: 257) 5 LAGE-1 MLMAQEALAFL (SEQ ID Aamoudse et al. Int J Cancer. NO: 233) 82(3):442-8 (1999). SLLMWITQC (SEQ ID NO: Rimoldi et al. J Immunol. 230) 165(12):7253-61 (2000). LAAQERRVPR (SEQ ID Wang et al. J Immunol. 161(7):3598- NO: 236) 606 (1998). ELVRRILSR (SEQ ID NO: Sun et al. Cancer Immunol 314) Immunother. 55(6):644-52 (2006). APRGVRMAV (SEQ ID Slager et al. Cancer Gene Ther. NO: 315) 11(3):227-36 (2004). SLLMWITQCFLPVF (SEQ  Zeng et al. Proc Natl Acad Sci U S ID NO: 244) A. 98(7):3964-9 (2001). QGAMLAAQERRVPRAAE Slager et al. J Immunol. VP-R (SEQ ID NO: 249) 172(8):5095-102 (2004). AADHRQLQLSISSCLQQL Jager et al. J Exp Med. 191(4):625- (SEQ ID NO: 253) 30 (2000). CLSRRPWKRSWSAGSCP Slager et al. J Inununol. G-MPHL (SEQ ID NO: 316) 170(3):1490-7 (2003). ILSRDAAPLPRPG (SEQ ID Wang et al. Immunity. 20(1):107-18 NO: 317) (2004). AGATGGRGPRGAGA Hasegawa et al. Clin Cancer Res. (SEQ ID NO: 257) 12(6):1921-7 (2006). 6 HERV-K-MEL MLAVISCAV (SEQ ID NO: Schiavetti et al. Cancer Res. 309) 62(19):5510-6 (2002). 7 KK-LC-1 RQICRILVNL (SEQ ID NO: Fukuyama et al. Cancer Res. 310) 66(9):4922-8 (2006). 8 KM-HN-1 NYNNFYRFL (SEQ ID NO: Fukuyama et al. Cancer Res. 311) 66(9):4922-8 (2006). EYSKECLKEF (SEQ ID Monji et al. Clin Cancer Res. 10(18 NO: 312) Pt 1):6047-57 (2004). EYLSLSDKI (SEQ ID NO: 313) 9 Sp17 ILDSSEEDK (SEQ ID NO: Chiriva-Internati et al. Int J Cancer. 299) 107(5):863-5 (2003).

TABLE 25 Brain cancer Tumor- associated Reported immunogenic No.  antigen epitopes Sources 1 TAG-1 SLGWLFLLL (SEQ ID NO: Adair et al. J Immunother. 31(1):7- 328) 17 (2008). LSRLSNRLL (SEQ ID NO: 329) 2 TAG-2 LSRLSNRLL (SEQ ID NO: Adair et al. J Immunother. 31(1):7- 329) 17 (2008).

TABLE 26 Pharynx cancer Tumor- associated Reported immunogenic No.  antigen epitopes Sources 1 TAG-1 SLGWLFLLL (SEQ ID NO: Adair et al. J Immunother. 31(1):7- 328) 17 (2008). LSRLSNRLL (SEQ ID NO: 329) 2 TAG-2 LSRLSNRLL (SEQ ID NO: Adair et al. J Immunother. 31(1):7- 329) 17 (2008).

TABLE 27 Tumors of the tongue Tumor- associated Reported immunogenic No.  antigen epitopes Sources 1 TAG-1 SLGWLFLLL (SEQ ID NO: Adair et al. J Immunother. 31(1):7- 328) 17 (2008). LSRLSNRLL (SEQ ID NO: 329) 2 TAG-2 LSRLSNRLL (SEQ ID NO: Adair et al. J Immunother. 31(1):7- 329) 17 (2008).

TABLE 28 Synovial cell sarcoma Tumor- associated Reported immunogenic No.  antigen epitopes Sources 1 LAGE-1 MLMAQEALAFL (SEQ ID Aamoudse et al. Int J Cancer. NO: 233) 82(3):442-8 (1999). SLLMWITQC (SEQ ID NO: Rimoldi et al. J Immunol. 230) 165(12):7253-61 (2000). LAAQERRVPR (SEQ ID Wang et al. J Immunol. NO: 236) 161(7):3598-606 (1998). ELVRRILSR (SEQ ID NO: Sun et al. Cancer Immunol 314) Immunother. 55(6):644-52 (2006). APRGVRMAV (SEQ ID Slager et al. Cancer Gene Ther. NO: 315) 11(3):227-36 (2004). SLLMWITQCFLPVF (SEQ Zeng et al. Proc Natl Acad Sci U S ID NO: 244) A. 98(7):3964-9 (2001). QGAMLAAQERRVPRAAE Slager et al. J Immunol. VP-R (SEQ ID NO: 249) 172(8):5095-102 (2004). AADHRQLQLSISSCLQQL Jager et al. J Exp Med. 191(4):625- (SEQ ID NO: 253) 30 (2000). CLSRRPWICRSWSAGSCP Slager et al. J Immunol. G-MPHL (SEQ ID NO: 316) 170(3):1490-7 (2003). ILSRDAAPLPRPG (SEQ ID  Wang et al. Immunity. 20(1):107-18 NO: 317) (2004). AGATGGRGPRGAGA Hasegawa et al. Clin Cancer Res. (SEQ ID NO: 257) 12(6):1921-7 (2006). 2 NY-ESO-1 LA-A2-restricted peptide Jager et al. Proc. Natl. Acad. Scie. p157-165 (SLLMWITQC U.S.A. 103(39):14453-8 (2006). (SEQ ID NO: 230)), HLA- Gmjatic et al. PNAS Cw3-restricted p92-100 September 26, 2000 vol. 97 no. 20 (LAMP-FATPM (SEQ ID p. 10919 NO: 231)) and HLA-Cw6- Jager et al. J Exp Med. 187(2):265- restricted p80-88 70 (1998). (ARGPESRLL (SEQ ID NO: Chen et al. J Immunol. 165(2):948- 232)) 55 (2000). SLLMWITQC (SEQ ID NO: Valmori et al. Cancer Res. 230) 60(16):4499-506 (2000). MLMAQEALAFL (SEQ ID Aamoudse et al. Int J Cancer. NO: 233) 82(3):442-8 (1999). YLAMPFATPME (SEQ ID Eikawa et al. Int J Cancer. NO: 234) 132(2):345-54 (2013). ASGPGGGAPR (SEQ ID Wang et al. J Immunol. NO: 235) 161(7):3598-606 (1998). LAAQERRVPR (SEQ ID Matsuzaki et al. Cancer Immunol NO: 236) Immunother. 57(8)1185-95 (2008). TVSGNILTIR (SEQ ID NO: Ebert et al. Cancer Res. 69(3):1046- 237) 54 (2009). APRGPHGGAASGL (SEQ Eikawa et al. Int J Cancer. ID NO: 238) 132(2):345-54 (2013). MPFATPMEAEL (SEQ ID Knights et al. Cancer Immunol NO: 239) Immunother. 58(3):325-38 (2009). KEFTVSGNILTI (SEQ ID Jager etal. Cancer Immun. 2:12 NO: 240) (2002). MPFATPMEA (SEQ ID Zeng et al. Proc Natl Acad Sci U S NO: 241) A. 98(7):3964-9 (2001). FATPMEAEL (SEQ ID NO: Mandic et al. J Immunol. 242) 174(3):1751-9 (2005). FATPMEAELAR (SEQ ID Chen et al. Proc Natl Acad Sci U S NO: 243) A. 101(25):9363-8 (2004). LAMPFATPM (SEQ ID Ayyoub et al. Clin Cancer Res. NO: 231) 16(18):4607-15 (2010). ARGPESRLL (SEQ ID NO: Slager et al. J Immunol. 232) 172(8):5095-102 (2004). SLLMWITQCFLPVF (SEQ  Mizote et al. Vaccine. 28(32):5338- ID NO: 244) 46 (2010). LLEFYLAMPFATPMEAEL Jager et al. J Exp Med. 191(4):625- -ARRSLAQ (SEQ ID NO: 30 (2000). 245) Zarour et al. Cancer Res. EFYLAMPFATPM (SEQ ID 60(17):4946-52 (2000). NO: 246) Zeng et al. J Immunol. 165(2):1153- PGVLLICEFTVSGNILTIRL 9(2000). -TAADHR (SEQ ID NO: Bioley et al. Clin Cancer Res. 247) 15(13):4467-74 (2009). RLLEFYLAMPFA (SEQ ID Zarour et al. Cancer Res. 62(1):213- NO: 248) 8 (2002). QGAMLAAQERRVPRAAE Hasegawa et al. Clin Cancer Res. -VPR (SEQ ID NO: 249) 12(6):1921-7 (2006). PFATPMEAELARR (SEQ ID NO: 250) PGVLLKEFTVSGNILTIRL T (SEQ ID NO: 251) VLLKEFTVSG (SEQ ID NO: 252) AADHRQLQLSISSCLQQL (SEQ ID NO: 253) LKEFTVSGNILTIRL (SEQ ID NO: 254) PGVLLKEFTVSGNILTIRL -TAADHR (SEQ ID NO: 247) LLEFYLAMPFATPMEAEL -ARRSLAQ (SEQ ID NO: 245) KEFTVSGNILT SEQ ID NO: 255) LLEFYLAMPFATPM (SEQ ID NO: 256) AGATGGRGPRGAGA (SEQ ID NO: 257) 3 HERV-K-MEL MLAVISCAV (SEQ ID NO: Schiavetti et al. Cancer Res. 309) 62(19):5510-6 (2002). 4 KK-LC-1 RQKRILVNL (SEQ ID NO: Fukuyama et al. Cancer Res. 310) 66(9):4922-8 (2006). 5 KM-HN-1 NYNNFYRFL (SEQ ID NO: Fukuyama et al. Cancer Res. 311) 66(9):4922-8 (2006). EYSKECLKEF (SEQ ID  NO: 312) EYLSLSDKI (SEQ ID NO: 313) 6 Sp17 ILDSSEEDK (SEQ ID NO: Chiriva-Internati et al. Int J Cancer. 299) 107(5):863-5 (2003).

TABLE 29 Neuroblastoma Tumor- associated Reported immunogenic No.  antigen epitopes Sources 1 LAGE-1 MLMAQEALAFL (SEQ ID Aamoudse et al. Int J Cancer. NO: 233) 82(3):442-8 (1999). SLLMWITQC (SEQ ID NO: Rimoldi et al. J Immunol. 230) 165(12):7253-61 (2000). LAAQERRVPR (SEQ ID et al. J Immunol. 161(7):3598- NO: 236) 606 (1998). ELVRRILSR (SEQ ID NO: Sun et al. Cancer Immunol 314) Immunother. 55(6):644-52 (2006). APRGVRMAV (SEQ ID Slager et al. Cancer Gene Ther. NO: 315) 11(3):227-36 (2004). SLLMWITQCFLPVF (SEQ Zeng et al. Proc Natl Acad Sci U S ID NO: 244) A. 98(7):3964-9 (2001). QGAMLAAQERRVPRAAE Slager et al. J Immunol. VP-R (SEQ ID NO: 249) 172(8):5095-102 (2004). AADHRQLQLSISSCLQQL Jager et al. J Exp Med. 191(4):625- (SEQ ID NO: 253) 30 (2000). CLSRRPWICRSWSAGSCP Slager et al. J Inununol. G-MPHL (SEQ ID NO: 316) 170(3):1490-7 (2003). ILSRDAAPLPRPG (SEQ ID Wang et al. Immunity. 20(1):107-18 NO: 317) (2004). AGATGGRGPRGAGA Hasegawa et al. Clin Cancer Res. (SEQ ID NO: 257) 12(6):1921-7 (2006). 2 NY-ESO-1 HLA-A2-restricted peptide Jager et al. Proc. Natl. Acad. Scie. p157-165 (SLLMWITQC U.S.A. 103(39):14453-8 (2006). (SEQ ID NO: 230)), HLA- Gnjatic et al. PNAS Cw3-restricted p92-100 September 26, 2000 vol. 97 no. 20 p. (LAMP-FATPM (SEQ ID 10919 NO: 231)) and HLA-Cw6- Jager et al. J Exp Med. 187(2):265- restricted p80-88 70 (1998). (ARGPESRLL (SEQ ID NO: Chen et al. J Immunol. 165(2):948- 232)) 55 (2000). SLLMWITQC (SEQ ID NO: Valmori et al. Cancer Res. 230) 60(16):4499-506 (2000). MLMAQEALAFL (SEQ ID Aamoudse et al. Int J Cancer. NO: 233) 82(3):442-8 (1999). YLAMPFATPME (SEQ ID Eikawa et al. Int J Cancer. NO: 234) 132(2):345-54 (2013). ASGPGGGAPR (SEQ ID Wang et al. J Immunol. 161(7):3598- NO: 235) 606 (1998). LAAQERRVPR (SEQ ID Matsuzald et al. Cancer Immunol NO: 236) Immunother. 57(8)1185-95 (2008). TVSGNILTIR (SEQ ID NO: Ebert et al. Cancer Res. 69(3):1046- 237) 54 (2009). APRGPHGGAASGL (SEQ  Eikawa et al. Int J Cancer. ID NO: 238) 132(2):345-54 (2013). MPFATPMEAEL (SEQ ID Knights et al. Cancer Immunol NO: 239) Imununother. 58(3):325-38 (2009). KEFTVSGNLLTI (SEQ ID Jager et al. Cancer Immun. 2:12 NO: 240) (2002). MPFATPMEA (SEQ ID Zeng et al. Proc Natl Acad Sci U S NO: 241) A. 98(7):3964-9 (2001). FATPMEAEL SEQ ID NO: Mandic et al. J Immunol. 242) 174(3):1751-9 (2005). FATPMEAELAR (SEQ ID Chen et al. Proc Natl Acad Sci U S NO: 243) A. 101(25):9363-8 (2004). LAMPFATPM (SEQ ID Ayyoub et al. Clin Cancer Res. NO: 231) 16(18):4607-15 (2010). ARGPESRLL (SEQ ID NO: Slager et al. J Immunol. 232) 172(8):5095-102 (2004). SLLMWITQCFLPVF (SEQ Mizote et al. Vaccine. 28(32):5338- ID NO: 244) 46 (2010). LLEFYLAMPFATPMEAEL Jager et al. J Exp Med. 191(4):625- -ARRSLAQ (SEQ ID NO: 30 (2000). 245) Zarour et al. Cancer Res. EFYLAMPFATPM SEQ ID 60(17):4946-52 (2000). NO: 246) Zeng et al. J Immunol. 165(2):1153- PGVLLKEFTVSGNILTIRL 9(2000). -TAADHR (SEQ ID NO: Bioley et al. Clin Cancer Res. 247) 15(13):4467-74 (2009). RLLEFYLAMPFA SEQ ID Zarour et al. Cancer Res. 62(1):213 NO: 248) 8 (2002). QGAMLAAQERRVPRAAE Hasegawa et al. Clin Cancer Res. -VPR (SEQ ID NO: 249) 12(6):1921-7 (2006). PFATPMEAELARR(SEQ ID NO: 250) PGVLLKEFTVSGNILTIRL T (SEQ ID NO: 251) VLLKEFTVSG (SEQ ID NO: 252) AADHRQLQLSISSCLQQL (SEQ ID NO: 253) LKEFTVSGNILTIRL (SEQ ID NO: 254) PGVLLKEFTVSGNILTIRL -TAADHR (SEQ ID NO: 247) LLEFYLAMPFATPMEAEL -ARRSLAQ (SEQ ID NO: 245) KEFTVSGNILT (SEQ ID NO: 255) LLEFYLAMPFATPM (SEQ ID NO: 256) AGATGGRGPRGAGA (SEQ ID NO: 257) 3 HERV-K-MEL MLAVISCAV (SEQ ID NO:  Schiavetti et al. Cancer Res. 309) 62(19):5510-6 (2002). 4 KK-LC-1 RQKRILVNL (SEQ ID NO: Fukuyama et al. Cancer Res. 310) 66(9):4922-8 (2006). 5 KM-HN-1 NYNNFYRFL (SEQ ID NO: Fukuyama et al. Cancer Res. 311) 66(9):4922-8 (2006). EYSKECLKEF (SEQ ID Monji et al. Clin Cancer Res. 10(18 NO: 312) Pt 1):6047-57 (2004). EYLSLSDKI (SEQ ID NO: 313) 6 Sp17 ILDSSEEDK (SEQ ID NO: Chiriva-Internati et al. Int J Cancer. 299) 107(5):863-5 (2003).

TABLE 30 Uterine cancer Tumor-associated Reported immunogenic No.  antigen epitopes Sources 1 LAGE-1 MLMAQEALAFL (SEQ ID Aarnoudse et al. Int J Cancer. NO: 233) 82(3):442-8 (1999). SLLMWITQC (SEQ ID NO: Rimoldi et al. J Immunol. 230) 165(12):7253-61 (2000). LAAQERRVPR (SEQ ID Wang et al. J Immunol. 161(7):3598- NO: 236) 606 (1998). ELVRRILSR (SEQ ID NO: Sun et al. Cancer Immunol 314) Immunother. 55(6):644-52 (2006). APRGVRMAV SEQ ID Slager et al. Cancer Gene Ther. NO: 315) 11(3):227-36 (2004). SLLMWITQCFLPVF (SEQ Zeng et al. Proc Natl Acad Sci U S ID NO: 244) A. 98(7):3964-9 (2001). QGAMLAAQERRVPRAAE Slager et al. J Immunol. VP-R (SEQ ID NO: 249) 172(8):5095-102 (2004). AADILIZQLQLSISSCLQQL Jager et al. J Exp Med. 191(4):625- (SEQ ID NO: 253) 30 (2000). CLSRRPWICRSWSAGSCP Slager et al. J Immunol. G-MPHL SEQ ID NO: 316) 170(3):1490-7 (2003). ILSRDAAPLPRPG(SEQ ID Wang et al. Immunity. 20(1):107-18 NO: 317) (2004). AGATGGRGPRGAGA Hasegawa et al. Clin Cancer Res. (SEQ ID NO: 257) 12(6):1921-7 (2006). 2 NY-ESO-1 HLA-A2-restricted peptide Jager et at. Proc. Natl. Acad. Scie. p157-165 (SLLMWITQC U.S.A. 103(39):14453-8 (2006). (SEQ ID NO: 230)), HLA- Gnjatic et al. PNAS Cw3-restricted p92-100 September 26,2000 vol. 97 no. 20 p. (LAMP-FATPM SEQ ID 10919 NO: 231)) and HLA-Cw6- Jager et al. J Exp Med. 187(2):265- restricted p80-88 70 (1998). (ARGPESRLL (SEQ ID NO: Chen et al. J Immunol. 165(2):948- 232)) 55 (2000). SLLMWITQC (SEQ ID NO: Valmori et al. Cancer Res. 230) 60(16):4499-506 (2000). MLMAQEALAFL (SEQ ID Aamoudse et al. Int J Cancer. NO: 233) 82(3):442-8 (1999). YLAMPFATPME (SEQ ID Eikawa et al. Int J Cancer. NO: 234) 132(2):345-54 (2013). ASGPGGGAPR (SEQ ID Wang et al. J Immunol. 161(7):3598- NO: 235) 606 (1998). LAAQERRVPR (SEQ ID Matsuzald et al. Cancer Immunol NO: 236) Immunother. 57(8)1185-95 (2008). TVSGNILTIR (SEQ ID NO: Ebert et al. Cancer Res. 69(3):1046- 237) 54 (2009). APRGPHGGAASGL (SEQ Eikawa et al. Int J Cancer. ID NO: 238) 132(2):345-54 (2013). MPFATPMEAEL (SEQ ID Knights et al. Cancer Immunol NO: 239) Immunother. 58(3):325-38 (2009). KEFTVSGNILTI (SEQ ID Jager et al. Cancer Immun. 2:12 NO: 240) (2002). MPFATPMEA (SEQ ID Zeng et al. Proc Nat! Acad Sci U S NO: 241) A. 98(7):3964-9 (2001). FATPMEAEL SEQ ID NO: Mandic et al. J Immunol. 242) 174(3):1751-9 (2005). FATPMEAELAR (SEQ ID Chen et al. Proc Natl Acad Sci U S NO: 243) A. 101(25):9363-8 (2004). LAMPFATPM (SEQ ID Ayyoub et al. Clin Cancer Res. NO: 231) 16(18):4607-15 (2010). ARGPESRLL (SEQ ID NO: Slager et al. J Immunol. 232) 172(8):5095-102 (2004). SLLMWITQCFLPVF (SEQ Mizote et al. Vaccine. 28(32):5338- ID NO: 244) 46 (2010). LLEFYLAMPFATPMEAEL Jager et al. J Exp Med. 191(4):625- -ARRSLAQ (SEQ ID NO: 30 (2000). 245) Zarour et al. Cancer Res. EFYLAMPFATPM (SEQ ID 60(17):4946-52 (2000). NO: 246) Zeng et al. J Immunol. 165(2):1153- PGVLLKEFTVSGNILTIRL 9(2000). -TAADHR (SEQ ID NO: Bioley et at. Clin Cancer Res. 247) 15(13):4467-74 (2009). RLLEFYLAMPFA (SEQ ID Zarour et al. Cancer Res. 62(1):213- NO: 248) 8 (2002). QGAMLAAQERRVPRAAE Hasegawa et al. Clin Cancer Res. -VPR (SEQ ID NO: 249) 12(6):1921-7 (2006). PFATPMEAELARR (SEQ ID NO: 250) PGVLLKEFTVSGNILTIRL T (SEQ ID NO: 251) VLLKEFTVSG (SEQ ID NO: 252) AADHRQLQLSISSCLQQL (SEQ ID NO: 253) LKEFTVSGNILTIRL (SEQ ID NO: 254) PGVLLKEFTVSGNILTIRL -TAADHR (SEQ ID NO: 247) LLEFYLAMPFATPMEAEL -ARRSLAQ (SEQ ID NO: 245) KEFTVSGNILT (SEQ ID NO: 255) LLEFYLAMPFATPM (SEQ ID NO: 256) AGATGGRGPRGAGA (SEQ ID NO: 257) 3 HERV-K-MEL MLAVISCAV (SEQ ID NO: Schiavetti el al. Cancer Res. 309) 62(19):5510-6 (2002). 4 KK-LC-1 RQKRILVNL (SEQ ID NO: Fukuyama et al. Cancer Res. 310) 66(9):4922-8 (2006). 5 KM-HN-1 NYNNFYRFL (SEQ ID NO: Fukuyama et al. Cancer Res. 311) 66(9):4922-8 (2006). EYSKECLKEF(SEQ ID Monji et al. Clin Cancer Res. 10(18 NO: 312) Pt 1):6047-57 (2004). EYLSLSDKI (SEQ ID NO: 313) 6 Sp17 ILDSSEEDK (SEQ ID NO: Chiriva-Internati et al. Intr J Cancer. 299) 107(5):863-5 (2003).

Gene Alignment

An exemplary alignment of select orthopoxvirus genes is shown below. Various genes of 5 vaccinia virus strains, Copenhagen (“cop”), Western Reserver (“WR”), Tian Tan (“Tian”), Wyeth, and Lister, align as follows:

C2L CLUSTAL 0(1.2.4) multiple sequence alignment (SEQ ID NOS 522-526, respectively, in   order of appearance) cop MESVIFSINGEIIQVNKEIITASPYNFFKRIQDHHLKDEAIIINGINYHAFESLLDYIRW 60 WR MESVIFSINGEIIQVNKEIITASPYNFFKRIQDHHLKDEAIILNGINYHAFESILDYIRW 60 Tian MESVIFSINGEIIQVNKEIITASPYNFFKRIQDHHLKDEAIILNGINYHAFESLLDYIRW 60 Wyeth MESVTFSINGEIIQVNKEIITASPYNFFKRIQEHHINDEVIILNGINYHAFESLLDYMRW 60 Lister MESVIFSINGEIIQVNKEIITASPYNFFKRIQDRHLKDEAIILNGINYHAFESLLDYMRW 60 **** ***************************:**::**.*****************:** cop KKINITINNVEMILVAAIIIDVPPVVDLCVKTMIHNINSTNCIRMENFSKRYGIKKLYNA 120 WR KKINITINNVEMILVAAIIIDVPPVVDLCVKTMIHNINSTNCIRMENFSKRYGIKKLYNA 120 Tian KKINITINNVEMILVAAIIIDVPPVVDLCVKTMIHNINSTNCIRMENFSKQYGIKKLYNA 120 Wyeth KKINITINNVEMILVAAVIIDVTPVVDLCVKTMIHNINSTNCIRMFNESKRYGIKKLYNA 120 Lister KKINITINNVEMILVAAIIIDVPPVVDLCVKTMIHNINFTNCIRMFNFSKRYGIKKLYNA 120 *****************:**** *************** ***********:********* cop SMSEIINNITAVTSDPEFGKLSKDELTTILSHENVNVNHEDVTAMILLKWIHKNPNDVDI 180 WR SMSEIINNITAVTSDPEFGKLSKDELTTILSHENVNVNHEDVTAMILLKWIHKNPNDVDI 180 Tian SMSEIINNITAVTSDPEFGKLSKDELTTILSHEDVNVNHEDVTAMILLKWIHKNPNDVDI 180 Wyeth SMSEIINNITAVTSDPEFGKLSKDELTTILSHEDVNVNHEDVTAMILLKWIHKNPNDVDI 180 Lister SMSEIINNITAVTSDPEFGKLSKDELTTILSHEDVNVNHEDVTAMILLKWIHKNPNDVDI 180 *********************************:************************** cop INILHPKFMTNTMRNAISLLGLTISKSTKPVTANGIKHNIVVIKNSDYISTITHYSPRTE 240 WR INILHPKFMTNTMRNAISLLGLTISKSTKPVTANGIKHNIVVIKNSDYISTITHYSPRTE 240 Tian INILHPKFMTNTMRNAISLLGLTISKSTKPVTANGIKHNIVVIKNSDYISTITHYSPRTE 240 Wyeth INILHPKFMTNTMRNAISLLGLTISKSTKPVTANGIKHNIVVIKNSDYISTITHYSPRTE 240 Lister INILHPKFMTNTMRNAISLLGITISKSTKPVTANGIKHNIVVIKNSDYISTITHYSPRTE 240 ************************************************************ cop YWTIVGNTDRQFYNANVIENCLYIIGGMINNRHVYSVSRVDLETKKWKTVTNMSSLKSEV 300 WR YWTIVGNTDRQFYNANVLHNCLYIIGGMINNAHVYSVSRVDLETKKWKTVTNMSSLKSEV 300 Tian YWTIVGNTDRQFYNANVIHNCLYIIGGMINNAHVYSVSRVDLETKKWKTVTNMSSLKSEV 300 Wyeth YWTIVGNTDRQFYNANVIHNCLYIIGGMINNAHVYSVSRVDLETKKWKTVTNMSSLKSEV 300 Lister YWTIVGNTDRQFYNANVIHNCLYIIGGMINNAHVYSVSRVDIKTKKWKTVTNMSSLKSEV 300 *******************************************:**************** cop STCVNDGKLYVIGGLEFSISTGVAEYLKHGTSKWIRLPNLITPRYSGASVFVNDDIYVMG 360 WR STCVNDGKLYVIGGLEFSISTGVAEYLKHGTSKWIRLPNLITPRYSGASVFVNDDIYVMG 360 Tian STCVNNGKLYVIGGLEFSISTGVAEYLKHGTSKWIRLPNLITPRYSGASVFVNDDIYVMG 360 Wyeth STCVNNGKLYVIGGLEFSISTGVAEYLKHGTSKWIRLPNLITPRYSGASVFVNDDIYVMG 360 Lister STCVNDGKLYVIGGLEFSISTGVAEYLKHGTSKWIRLPNLITPRYSGASVFVNDDIYVMG 360 *****:****************************************************** cop GVYTTYEKYVVLNDVECETKNRWIKKSPMPRHHSIVYAVEYDGDIYVITGITHETRNYLY 420 WR GVYTTYEKYVVLNDVECETKNRWIKKSPMPRHESIVYAVEYDGDIYVITGITHETRNYLY 420 Tian GVYTTYEKYVVLNDVECETKNRWIKKSPMPRHHSIVYAVEYDGDIYVITGITHETRNYLY 420 Wyeth GVYTTYEKYVVLNDVECFTKNRWIKKSPMPRHHSIVYAVEYDGDIYAITGITHETRNYLY 420 Lister GVYTTYEKYVVLNDVECFTKNRWIKKSPMPRHHSIVYAVEYDGDIYVITGITHETRNYLY 420 **********************************************.************* cop KYIVREDKWIELYMYENHVGKMFVCSCGDYILIIADAKYEYYPKSNTWNLEDMSTRNIEY 480 WR KYIVKEDKWIELYMYFNHVGKMFVCSCGDYILIIADAKYEYYPKSNTWNLFDMSTRNIEY 480 Tian KYIVKEDKWIELYMYFNHVGKMFVCSCGDYILIIADAKYETYPKSNTWNLFDMSTRNIEY 480 Wyeth KYIVKEDKWIELYMYENHVGKMFVCSCGDYILIIADAKYEYYPKSNTWNLEDMSTRNIEY 480 Lister KYIVKEDKWIELYMYENHVGKMFVCSCGDYILIIADAKYEYYPKSNTWNLEDMSTRNIEY 480 ************************************************************ cop YDMETKDETPKCNVTHKSLPSFLSNCEKQFLQ 512 WR YDNFTKDETPKCNVTHKSLPSFLSNCEKQFLQ 512 Tian YDNFTKDETPKCNVTHKSLPSFLSNCEKQFLQ 512 Wyeth YDMFTKDET------HKSLPSFLSNCEKQFLQ 506 Lister YDMETKDETPKONVTHKSLPSFLSNCEKQFLQ 512 ********* ***************** c1L CLUSTAL 0(1.2.4) multiple sequence alignment (SEQ ID NOS 527-531, respectively, in  order of appearance) Cop MVKNNKI-----SNSCRMIMSTNPNNILMRHLKULTDDEFKCIIHRSSDFLYLSDSDYTS 55 WR MVKNNKIQKNKISNSCRMIMSTDPNNILMRHLKNLTDDEFKCIIHRSSDFLYLSDSDYTS 60 Tian MVKNNKI-----SNSCRMINSTDPNNILMRHLKNLTDDEFKCIIHRSSDFLYLSDSDYTS 55 Wyeth MVKNNKI-----SNSCRMINSTNPNNILMRHLKNLTDDEFKCIIHRSSDFLYLSDRDYTS 55 Lister MVRNNKI-----SNSCRMIMSTNPNNILMRHLKNLTDDEFKCIIHRSSDFLYLSDSDYTS 55 ******* ************************************************ Cop ITKETLVSEIVEEYPDDCNKILAIIFLVLDKDIDVDIETKLITKPAVRFAILDRMTEDIK 115 WR ITKETLVSEIVEEYPDDCNKILAIIFLVLDKDIDVDIKTKLKPKPAVRFAILDINTEDIK 120 Tian ITKETLVSEIVEEYPDDCNKILAIIFLVLDKDIDVDIKTKLITKPAVRFAILDKMTEDIK 115 Wyeth ITKETLVSEIVEEYFDDCNKILAIIFLVLDKDIDVDIKTKLKPKPAVRFAILDKMTEDIK 115 Lister ITKETLVSEIVEEYPDDCNKILAIIFLVLDKDIDVDIETKLKPKPAVRFAILDINTADIK 115 *************************************:********************** Cop LTDLVRRYFRYIEQDIPLGPLFKKIDSYRTRAINKYSKELGLATEYFNKYGHLMFYTLPI 175 WR LTDLVRHYFRYIEQDIPLGPLFKKIDSYRTRAINKYSKELGLATEYFNKYGHLMFYTLPI 180 Tian LTDLVRHYFRYIEQDIPLGPLFKKIDSYRTRAINKYSKELGLATEYFNKYGHLMFYTLPI 175 Wyeth LTDLVRHYFRYIEQDIPLGPLFRKIDSYRTRAINKYSKELGLATEYFNKYGHLMFYTLPI 175 Lister LTDLVRHYFRYIEQDIPLGPLFKKIDSYRTRAINRYSKELGLATEYFNRYGHLMFYTLPI 175 ************************************************************ Cop PYNRFFCRNSIGFLAVISPTIGHVKAFYKFIEYVSIDDRRKFKKELMSK 224 WR PYNRFFCRNSIGFLAVLSPTIGHVKAFYKFIEYVSIDDRRKFKKELMSK 229 Tian PYNRFFCRNSIGFLAVLSPTIGHVKAFYKFIEYVSIDDRRKFKKELMSK 224 Wyeth PYNRFFCRNSIGFLAVISPTIGHVKAFYKFIEYVSIDDRRKFKKELMSK 224 Lister PYNRFFCRNSIGFLAVLSPTIGHVKAFYRFIEYVSIDDRRKFKKELMSK 224 ************************************************* N1L CLUSTAL 0(1.2.4) multiple sequence alignment (SEQ ID NOS 532-536, respectively, in  order of appearance) Cop MTYLLIRYILWANDNDQTYYNDNFKKLMILDELVDDGDVCTLIKNNRMTLSDGPLLDRLN 60 WR MRTLLIRYILWANDNDQTYYNDNFKKLMILDELVDDGDVCTLIKNNRMTLSDGPLLDRLN 60 Tian MRTLLIRYILWRNDNDQTYYNDDFKKLMLLDELVDDGDVCTLIKNMRMTLSDGPLLDRLN 60 Wyeth MRTLLIRYILWANDNDQTYYNDDFKKLMILDELVDDGDVCTLIKNMRMTLSDGPLLDRLN 60 Lister MRTLLIRYILWRNDNDQTYYNDDFKKLMLLDELVDDGDVCTLIKNMRMTLSDGPLLDRLN 60 **********************:************************************* Cop QPVNNIEDAKRMIAISAKVARDIGERSEIRWEESFTILFRMIETYFDDLMIDLYGEK 117 WR QPVNNIEDARRMIAISARVARDIGERSEIRWEESFTILFRMIETYFDDLMIDLYGEK 117 Tian QPVNNIEDAERMIAISAKVARDIGERSEIRWEESFTILFRMIETYFDDLMIDLYGEK 117 Wyeth QPVNNIEDAKRMIAISARVARDIGERSEIRWEESFTILFRMIETYFDDLMIDLYGEK 117 Lister QPVNNIEDAKRMSAISAKVARDIGERSEIRWEESFTILFRMIETYFDDLMIDLYGEK 117 ********************************************************* N2L CLUSTAl 0(1.2.4) multiple sequence alignment (SEQ ID NOS 537-541, respectively, in  order of appearance) Cop MTSSAMDNNEPHVLEMVYDATILPEGSSMDPNIMDCINRHINMCIQRTYSSSIIAILNRF 60 WR MTSSANDNNEPKVLEMVYDATILPEGSSMDPNIMDCINRHINMCIQRTYSSSIIAILDRF 60 Tian MTSSAMDNNEFKVLEMVTDATILPEGSSMDPYINDCINRHINMCIQRTYSSSIIAILDRF 60 Wyeth MTSSAMDNNEPKVLEMVYDATILPEGSSMDPNIIDCINREINMCIQRTYSSSIIAILDRF 60 Lister MTSSANDNNEPKVLENVYDATILPEGSSMDPNIMDCINRHINMCIQRTYSSSIIAILDRF 60 ******************************* *:***********************:** Cop LTMNKDELNNTQCHIIREFMTYEQMAIDHYGEYVNAILYQIRKRPNQHHTIDLFKKIRRT 120 WR LMMNKDELNNTQCHIIKEFMTYEQMAIDHYGGYVNAILYQIRKRPNQHRTIDLFKRIKRT 120 Tian LMMNKDELNNTQCHIIKNL----------------------------------------- 79 Wyeth LTMNKDELNNTQCHIIKEFMTYEQMAIDHYGGYVNAILYQIRRRPNQHHTIDLFKKIKRT 120 Lister LTMNRDELNNTQCHIIKEFMIYEQMAIDHYGEYVNAILYQIRERPNQHRTIDLFKKIKRT 120 * ***************:: Cop PYDTFKVDPVEFVKKVIGFVSILNKYKPVYSYVLYENVLYDEFKCFINYVETRYF 175 WR RYDTFKVDPVEEVKKVIGFVSILNKYKPVYSYVLYENVLYDEFKCFINYVETKYF 175 Tian ------------------------------------------------------- Wyeth RYDTFKVDPVEFVKKVIGFVSILNKYKPVYSYVLYENVLYDEFKCFIDYVETKYF 175 Lister RYDTFKVDPVEFVKKVIGFVSILNKYKPVYSYVLYENVINDEFKCFIDYVETRYF 175 M1L CLUSTAL 0(1.2.4) multiple sequence alignment (SEQ ID NOS 542-546, respectively, in  order of appearance) Cop MIEVIESKLLQIYRNRNRNINFYTTMDNIMSAEYYLSLYAKYNSKNLDVERNMLQAIEPS 60 WR MIETIESKLLQIYRNRNRNINFYTTMDNIMSAEYYLSLYAKYNSKNLDVERNMIQAIEPS 60 Tian MIETIESKLLQIYRNRNIININFYTTMDNIMSAEYYLSLYAKYNKNLDVERNMIQAIEPS 60 Wyeth MIFVIESKLLQIYRNRNRNINFYTTMDNIMSAEYYLSLYAKYNSKNLDVFRNMIQAIEPS 60 Lister MIFVIESKLLQIYRN--RNINFYTTMDNIMSAEYYLSLYAKYNSKNLDVFRNMLQAIEPS 58 *************** ******************************************* Cop GNNYHILHAYCGIKGLDERFVEELLHRGYSPNETDDDGNYPLHIASKINNNRIVAMILTH 120 WR GNNYHILHAYCGIKGLDERFVEELLHRGYSPNETDDDGNIPLHIASKINNNRIVAMILTH 120 Tian GNNYHILHAYCGIKGLDERFVEELLHRGYSPNETDDDGNIPLHIASKINNNRIVAMLLTH 120 Wyeth GNNYHILHAYCGIKGLDERFVEELLHRGYSPNETDDDGNYPLHIASKINNNRIVAMLLTH 120 Lister GNNYHILHAYCGIKGIDERFVEELLHRGYSPNETDDDGNYPLHIASKINNNRIVAMLLTH 118 ************************************************************ Cop GADPNACDKHNKTPLYYLSGTDDEVIERINLLVQYGAKINNSVDEEGCGPLIACTDPSER 180 WR GADPNACDKHNKTPLYYLSGTDDEVIERINLLVQYGAKINNSVDEEGCGPLIACTDPSER 180 Tian GADPNACDKHNKTPLYYLSGTDDEVIERINLLVQYGAKINNSVDEEGCGPLIACTDPSER 180 Wyeth GADPNACDKHNKTPLYYLSGTDDEVIERINLLVQYGAKINN------------------- 161 Lister GADPNACDKQHKTPLYYLSGTDDEVIERINLLVQYGAKINNSVDEEGCGPLLACTDPSER 178 *********::****************************** Cop VFKKIMSIGFEARIVDKFGKNHIHRHLMSDNPKASTISWMMKLGISPSKPDHDGNTPLHI 240 WR VFKKIMSIGFEARIVDKEGKNHIHRHLMEDNPKASTISWMMKIGISPSKPDHDGNIPLHI 240 Tian VEKKIMSIGFEARIVDKEGKNHIHRHLMSDNPKASTISWNMKLGISPSKPDHDGNTPLHI 240 Wyeth ------------------------------------------------------------ Lister VFKKIMSIGFEARIVDKEGKNHIHRHLMSDNPKASTISWMMFIGISPSKPDHDGNIPLHI 238 Cop VCSKTVKNVDIIDLLLPSTDVNKQNKFGDSPLILLIKILSPAHLINKLLSTSNVITDQTV 300 WR VCSKTVKNVDIIDLLLPSTDVNKQNKFGDSPLILLIKILSPAHLINKLLSTSNVITDQTV 300 Tian VCSKTVKNVDIIDLLLPSTDVNKQNKFGDSPLTLLIKTLSPAHLINKLLSTSNVITDQTV 300 Wyeth ------------------------------------------------------------ Lister VCSKTVFNVDIIDLLLPSTDVNKQNKFGDSPLILLIKILSPAHLINKLLSTSNVITDQTV 298 Cop NICIFYDRDDVIEIINDKGKQYDSTDFKMAVEVGSIRCVKYLLDNDIICEDAMYYAVISE 360 WR NICIFYDRDDVLEIINDKGKQYDSTDFKMAVEVGSIRCVKYLLDNDIICEDAMYYAVLSE 360 Tian NICIFYDRDDVLEIINDKGKQYDSTDFKMAVEVGSIRCVKYLLDNDIICEDAMYYAVLSE 360 Wyeth ------------------------------------------------------------ Lister NICIFYDRDDVIEIINDKGKQYDSTDFKMAVEVGSIRCVKYLLDNDIICEDAMYYAVLSE 358 Cop YETMVDYLLENHFSVDSVVNGHTCMSECVALNNPVILSKLMLHNPTSETMYLTMKAIEKD 420 WR YETMVDYLLFNHFSVDFVVNGHTCMSECVRLNNPVILSKLMLHNPTSETMYLTMKAIEKD 420 Tian YETMVDYLLFNHFSVDFVVNGHTCMSECVRLNNPVILSKLMLHNLTSETMYLTMKAIEKD 420 Wyeth ------------------------------------------------------------ Lister YETMVDYLLENHFSVDSVVNGHTCMSECVALNNPVILSKLMIHNPTSETMYLTMKAIEKD 418 Cop KLDKSIIIPFIAYFVLMHPDFCKNRRYFTSYKRFVTDYVHEGVSYEVEDDYF 472 WR RLDKSIIIPFIAYFVLMHPDFCKNRRYFTSYKRFVTDYVHEGVSIEVEDDYF 472 Tian RLDKSIIIPFIAYFVLMHPDFCKNRRYFTSYKREVTDYVHEGVSYEVEDDYF 472 Wyeth ---------------------------------------------------- Lister RLDKSIIIPFIAYFVLMHPDFCKNRRYFTSYKREVIDYVHEGVSYEVEDDYF 470 M2L CLUSTAL 0(1.2.4) multiple sequence alignment (SEQ ID NOS 547-551, respectively, in  order of appearance) Cop MVYKLVILFCIASLGYSVEYKNTICPPRQDYRYWYFAAELTIGVNYDINSTIIGECHMSE 60 WR MVYKLVLLFCIASLGYSVEYKNTICPPRQDYRYWYFAAELTIGVNYDINSTIIGECHMSE 60 Tian ------------------------MSSSTRLPVIVLAAELTIGVNYDINSTIIGECHMSE 36 Wyeth MVYKIVILFCIASLGYSVEYKNTICPPRQDYRYWYFAAELTIGVNYDINSTIIGECHMSE 60 Lister MVYK/VILFCIASLGYSVEYKNTICPPRQDYRYWYFAAELTIGVNYDINSTIIGECHMSE 60 Cop SYIDRNANIVLIGYGLEINMTIMDTDQREVAAAEGVGKONKLSVILFTTQRLDKVBHNIS 120 WR SYIDRNNANIVTGYGLEINNTIMDTDOREVAAAEGVGEDNKLSVLLFTTQRLDKVEHNIS 120 Tian SYIDRNANIVLTGYGLEINMTIMDTDQREVAAAEGVGKDNKLSVLLETTQRLDKVHBNIS 96 Wyeth SYIDRNANIVLTGYGLEINMTIMDTDQREVAAAEGVGKDNKISVLLFTTQRLDKVHHNIS 120 Lister SYIDRNANIVLTGYGLEINNTIMDTDQREVAAAEGVGKDNKLSVLLETTQRLDKVHENIS 120 ------------------------------------------------------------ Cop VTITCMEMNCGTTKYDSDLPESIHKSSSCDITINGSCVTCVNLETDPTKINPHYLHPKDK 180 WR VTITCMEMNCGTTKYDSDLPESIHKSSSCDITINGSCVTCVNLETDATKINPHYLHAKDK 180 Tian VTITCNEMNCGTTKYDSDLPESIEKSSSCDITINGSCVTCVNLETDATKINPHYLHPKDK 156 Wyeth VTITCMEMNCGTTKYDSDLPESIHKSSSCDITINGSCVTCVNLETDATKINPHYLHAKDK 180 Lister VTITCMEMNCGTTKYDSDLPESIHKSSSCDITINGSCVTCVNLETDATKINPHYLHAKDK 180 ------------------------------------------------------------ Cop YLYHNSEYGMRGSYGVTFIDELNQCLLDIKELSYDICYRE 220 WR YLYHNSEYSMRGSYGVTFIDELNQCLLDIKELSYDICYRE 220 Tian YLYHNSEYGMRGSYGVTFIDELNQCLLDIKELSYDICYRE 196 Wyeth YLYHNSEYGMRGSYGVTFIDELNQCLLDIKELSYDICYRE 220 Lister YLYHNSEYGMRGSYGVTFIDELNQCLLDIKELSYDICYRE 220 ********_******************************* K1L CLUSTAL 0(1.2.4) multiple sequence alignment (SEQ ID NOS 552-556, respectively,  in order of appearance) Cop MDLSRINTWKSKQLKSFLSSKDTFKADVHGHSALYYAIADNNVALVCTLLNAGALKNLLE 60 WR MDLSAINTWKSKQLKSFLSSKDAFKADVHGHSALYYAIADNNVRLVCTLLNAGALKNLLE 60 Tian MDLSAINTWKSKQLKSFLSSKDTFKADVHGHSALYYAIADNNVALVCTLLNSGALKNLLE 60 Wyeth MDLSRINTWKSKQLKSELSSKDTFKADVHGHSALYYAIADNNVALVCTLLNAGALKNLLE 60 Lister MDLSRINTWKSKQLKSELSSKDAFKADINGHSALYYAIADNNVALVCTLLNAGALKNLLE 60 **********************:****::**********************:******** Cop NEFPLHQAATLEDTKIVKILLFSGMDDSOFDDKGNTALYYAVDSGNMOTVKLFVKKNWRL 120 WR NEFPLHQAATLEDTKIVKILLFSGLDDSQFDDKGNTALYYAVDSGNMQTVKLFVKKNWAL 120 Tian NEFPLHQAATLEDTKIVKILLFSGLDDSQFDDKGNTALYYAVDSGNMQTVKLEVKKNWRL 120 Wyeth NEFPLHQAATLEDTKIVKILLFSGLDDSQFDDKGNTALYYAVDSGNMQTVKLEVKKNWRL 120 Lister NEFPLHQAATLEDTKIVKILLFSGLDDSQFDDKGNTALYYAVDSGNMQTVKLFVKKNWAL 120 ************************:*********************************** Cop MFYGKTGWKTSFYHAVMLNDVSIVSYFLSEIPSTFDLAILLSCIHTTIKNGHVDMMILLL 180 WR MFYGKTGWETSFYHAVMLNDVSIVSYFLSEIPSTFDLAILLSCIRITIKNGHVDMMILLL 180 Tian MFYGKTGWKTSFYHAVM11DVSIVSYFLSEIPSTFDLAILLSCIHITIKNGHVD8MILLL 180 Wyeth MFYGKTGWKTSFYHAVMLNDVSIVSYFLSEIPSTFDLAILLSCIHITIKNGHVDMMILLL 180 Lister MFYGKTGWKTSFYHAVMINDVSIVSYFLSEIPSTFDLAILLSCIHITIKNGHVDMMILLL 180 ********************************************* ************** Cop DYMTSTNTNNSLLFIPDIKLAIDNKDIEMLQALFKYDINIYSVNLENV1LDDAEITKMII 240 WR DYNTSTNTNNSLLFIPDIKLAIDNKDIEMLQALFKYDINIYSANLENVILDDAEIAKMII 240 Tian DYMTVDKHQ--------------------------------------------------- 189 Wyeth DYMTSTNTNNSLLFIADIKLAIDNKDIEMLQALFKYDINIYSANLENVLLDDAEIAKMII 240 Lister DYNTSTNTNNSLLFIPDIKLAIDNKDIEMIQALFKYDINIYSANLENVILDDAEIAKMII 240 **** : : Cop EKHVEYKSDSYTKDLDIVKNNKLDEIISKNKELRLMYVNCVKKN 284 WR EKHVEYKSDSYTKDLDIVKNNKLDEITSKNKELRLMYVNCVKKN 284 Tian -------------------------------------------- Wyeth EKHVEYKSDSYTKDLDIVKNNKLDEIISKNKELRLMYVNCVKEN 284 Lister EKHVEYKSDSYTKDLDIVKNNKLDETISKNKELKLMYVNCVRKN 284 K2L CLUSTAL 0(1.2.4) multiple sequence alignment (SEQ ID NOS 557-561, respectively, in   order of appearance) Cop MIAILILSLTCSVSTYRLOGFTNAGIVAYKNIQDDNIVFSPFGYSFSMFMSLLPASGNTR 60 WR MIALLILSLTCSVSTYRIQGFTNAGIVAYKNIODDNIVESPEGYSFSMEMSLLPASGNTR 60 Tian MIALLILSLACSASAYRLOGFTNAGIVAYKNIODDNIVFSPFGYSFSMFMSLLPASGNTR 60 Wyeth MIALLILSLTCSVSTYRLQGFTNAGIVAYKNIQDDNIVESPFGYSFSMEMSLLPASGNTR 60 Lister ------------------------------------------------------------ Cop IELLKTMDLRKRDLGPAFTELISGLAKLKTSKYTYTDLTYQSFVDNTVCIKPLYYQQYHR 120 WR IELLKTMDLRKRDLGPAFTELISGLAKLKTSKYTYTDLTYQSFVDNTVCIKPSYYQQYHR 120 Tian IELLKTMDLRKRDLGPAFTELISGLAKLKTSKYTYTDLTYQSFVDNTVCIKPSYYQQYHR 120 Wyeth IELLKTMDLRKRDLGPAFTELISGLAKLKTSKYTYTDLTYQSFVDNTVCIKPSYYQQYHR 120 Lister IELLKTMDLRKRDLGPAFTELISGLAKLKTSKYTYTDLTYQSFVDNTVCIKPSYYQQYHR 60 **************************************************** ******* Cop FGLYRINFRADAVNKINSIVERRSGMBNVVDSNMIDNNTLWAIINTIYFKGTWQYPFDIT 180 WR FGLYRLNFRRDAVNKINSIVERRSGMSNVVDSNMIDNNTLWAIINTIYFKGIWQYPFDIT 180 Tian FGLYRLNFRADAVNKINSIVERRSGMSNVVDSNMLDNNTLWAIINTIYFKGTWQYFFDIT 180 Wyeth -----LNFRADAVNKINSIVERRSGMSNVVDSNMIDNNTLWAIINTIYFKGIWQYFFDIT 175 Lister FGLYRLNFRRDAVNKINSIVERRSGMSNVVDSNMIDNNTLWAIINTIYFKGIWQYPFDIT 120 ********************************************** ******** Cop KTRNASFTNKYGTKTVPMMINVTKLQGNTITIDDEEYDMVRLPYKDANISMYLAIGDNET 240 WR KTRNASFTNKYGTKTVPMMNVVTKLQGNTITIDDEEYDMVRLPYKDANISMYLAIGDNMT 240 Tian KTRNASFTNKYGTKTVPMMNVVTKLQGNTITIDDEEYDMVRLPYKDANISMYLAIGDNNT 240 Wyeth KTRNASFTNXYGTKTVPMMINVTKLQGNTITIDDKEYDMVRLPYKDANISMYLAIGDNNT 235 Lister KTRNASFTNKYGTKTVPMMNVVTKLQGNTITIDDEEYDMVALPYKDANISMYLAIGDNMT 180 **********************************:************************* Cop HFTDSITAAKLDYWSFQLGNEVYNLKLPKFSIENKRDIKSIAEMMAPSMFNPDNASFKHM 300 WR HFTDSITAAKLDYWSFQLGNKVYNLKLPKFSIENKRDIKSIAEMMAPSMENPDNASFKHM 300 Tian HFTDSITAA-KDYWSFQLONKVYNLKLPKFSIENXRDIKSIAEMMAPSMFNPDNASFKHM 299 Wyeth HFTDSITAAKLDYWSFQLGNKVYNLKLPKFSIENKRDIKSIAEMMAPSMFNPDNASFKHM 295 Lister HFTDSITAAKLDYWSSQLGNKVYNLKLPKFSIENKRDIKSIAEMMAPSMFNPDNASFKHM 240 ********* **** ******************************************** Cop TRDPLYIYKMEQNAKIDVDEQGTVAEASTIMVATARSSPEKLEFNTPFVFIIRHDITGFI 360 WR TRDPLYIYKMFQNAKIDVDEQGTVARASTIMVATARSSPEKLEFNTPFVFIIRHDITGFI 360 Tian TRDPLYIYEMPQNAKIDVDEQGTVAEASTIMVATARSSPEELEFNTPFVFIIRHDITGFI 359 Wyeth TRDPLYIYKMFQNAKIDVDEQGTVAEASTIMVATARSSPEKLEFNTPFVFIIRHDITGFI 355 Lister TRDPLYIYKMFQNAKIDVDEQGTVAEASTIMVATARSSPEKLEFNTPFVFIIRHDITGFI 300 ************************************************************ Cop LFMGKVESP 369 WR LFMGKVESP 369 Tian LFMGKVESP 368 Wyeth LFMGKVESP 364 Lister LFMGKVESP 309 ********* K ORF A CLUSTAL 0(1.2.4) multiple sequence alignment (SEQ ID NOS 562-563, respectively, in  order of appearance) Cop MGHIITYCQVHTNISILIRKAHHIIFFVIDCDCISLQFSNYVHHGNRFRTVLISKTSIAC 60 Tian MGHIITYCQVHTNISILIRKAYHIIFFVIDCDCISLQFSNYVHHGNRFRTVLISKTSIAC 60 ************************************************************ Cop FSDIKRILPCTFKIYSINDCP 81 Tian FSDIKRILPCTFKIYSINDCP 81 ********************* K3L CLUSTAL 0(1.2.4) multiple sequence alignment (SEQ ID NOS 564-568, respectively, in  order of appearance) Cop MLAFCYSLPNAGDVIKGRVYEKDYALYIYLFDYPHSEAILAESVFMEMDRYVEYRDKLVG 60 WR MLAFCYSLPNAGDVIKGRVYEKDYALYIYLFDYPHFEAILAESVKMEMDRYVEYRDKLVG 60 Tian MLAFCYSLPNAGDVIKGRVYEKDYALYIYLFDYPHSEAILAESVXMEMDRYVEYRDKLVG 60 Wyeth MLAFCYSLPNAGDVIKGRVYENDYALYIYLFDYPHFEAILAESVKMHMDRYVEYRDXLVG 60 Lister MLAFCYSLPNAGDVIKGRVYENDYALYIYLFDYPHSEAILAESVKMEMDRYVEYRDKLVG 60 *********************:************* ************************ Cop KTVKVKVIRVDYTKGYIDVNYKRMCRHQ 88 WR KTVXVKVIRVDYTKGYIDVNYKRMCRHQ 88 Tian KTVKVKVIRVDYTKGYIDVNYKRMCRHQ 88 Wyeth KTVEVKVIRVDYTKGYIDVNYKRMCRHQ 88 Lister KTVKVXVIRVDYTKGYIDVNYKRMCRHQ 88 **************************** K4L CLUSTAL 0(1.2.4) multiple sequence alignment (SEQ ID NOS 569-572, respectively, in  order of appearance) Cop MNPDNTIAVITETIPIGMQFDKVYLSTFNMWREILSNTTKTLDISSFYWSLSDEVGTNFG 60 WR MNPDNTIAVITETIPIGMQFDKVYLSTFNMWREILSNITKTLDISSFYWSLSDEVGTNFG 60 Wyeth MNPDNTIAVITETIPIGMQFDKVYLSTFNMWREILSNTIKTLDISSFYWSLSDEVGTNFG 60 Lister MNPDNTIAVITETIPIGMQFDKVYLSTFNMWREILSNTTKTLDISSFYWSLSDEVGTNFG 60 ************************************************************ Cop TIILNEIVQLPKRGVRVRVAVNKSNKPLKDVERLQMAGVEVRYIDITNILGGVLHTKFWI 120 WR TIILNKIVQLPKRGVRVRVAVNKSNKPLKDVERLQMAGVEVRYIDITNILGGVLHTKFWI 120 Wyeth TIILNEIVQLPKRGVAVRVAVNKSNKPLKDVERLQMAGVEVRYIDITNILGGVLHTKFWI 120 Lister TIILNEIVQLPKRGVRVRVAVNKSNKPLKDVERLQMAGVEVRYIDITNILGGVLHTKFWI 120 *****:****************************************************** Cop SDNTHIYLGSANMDWRSLTQKELGIAIFNNANLAADLTQIFEVYWYLGVNNLPYNWKNF 180 WR SDNTHIYLGSANMDWRSLTQVKELGIAIFNNRLAADLTQIFEVYWYLGVNNLPYNWKNF 180 Wyeth SDNTHIYLGSANMDWRSLTQKELGIAIFNNRNLAADLIQIFEVYWYLGVNNLPYNWKNF 180 Lister SDNTHIYLGSANMDWRSLTQWELGIAIFNNRNLAADLIQIFEVYWYLGVNNLPYNWKNF 180 *********************************************************** Cop YPSYYNTDHPLSINVSGVPHSVFIASAPQQLCTMERTNDLTALLSCIRNASKFVYVSVMN 240 WR YPSYYNTDHPLSINVSGVPHSVFIASAPQQLCIMERTNDLTALLSCIRNASKFVYVSVMN 240 Wyeth YPSYYNTDHPLSINVSGVPHSVFIASAPQQLCTMERTNDLTALLSCIRNASKFVYVSVMN 240 Lister YPSYYNTDHPLSINVSGVPHSVFIASAPQQLCTMERTNDLTALLSCIRNASKFVYVSVMN 240 Cop FIPIIYSKAGKILFWPYIEDELARSAIDRQVSVKLLISCWQRSSFIMANFLRSIAMIKSK 300 WR FIPIIYSKAGNILFWPYIEDELRRAAIDRQVSVKLLISCWQRSSFIMANFLRSIAMIKSK 300 Wyeth FIPIIYSKAGKILFWPYIEDEL8RSAIDRQVSVKLLISCWQRSSFIMENFLRSIAMIKSK 300 Lister FIPIIYSKAGKILFWPYIEDELARSAIDRQVSVKLLISCWQRSSFIERNFLRSIAMIKSK 300 ************************************************************ Cop NIDIEVKLFIVPDADPPIPYSRVNHAKYMVTDKTAYIGTSNWTGNYFTDTCGASINITPD 360 WR NINIEVKLFIVPDADPPIPYSRVNEAKYMVTDKTAYIGTSNWTGNYFTDTCGASINITPD 360 Wyeth NINIEVKLFIVPDADPPIPYSRVNHAKYMVTDKTAYIGTSNWTGNYFTDTCGASINITPD 360 Lister NINIEVKLFIVPDADPPIPYSRVNHAKYMVTDKTAYIGTSNWTGNYFTDTCGASINITPD 360 **:********************************************************* Cop DGLGLRQQLEDIFMRDWNSKYSYELYDTSPTKRCKLLKNMKQCTNDIYCDEIQPEKEIPE 420 WR DGLGLRQQLEDIFMRDWNSKYSYELYDTSPTKRCALLKNMKQCTNDIYCDEIQPEKEIPE 420 Wyeth DGLGLRQQLEDIFMRDWNSKYSYELYDTSPTKRCKLLKNMKQCINDIYCDEIQPEKEIPE 420 Lister DGLGLRQQLEDIFMRDWNSKYSYELYDTSPTKRCKLLKNMEQCTNDIYCDEIQPEKEIPE 420 **********************************:************************* 420 Cop YSLE 424 WR YSLE 424 Wyeth YSLE 424 Lister YSLE 424 **** K5L CLUSTAL 0(1.2.4) multiple sequence alignment (SEQ ID NOS 573-577, respectively, in  order of appearance) Cop -------------MGATISILASYDNPNLFTAMILMSPLVNADAVSRLNLLAAKLMGTIT 47 WR MTLVQHVVTIKSTYWVIPWELASYDNPNLFTAMILMSPLVNADAVSKLNLLAAKINGTIT 60 Tian MTLVQHVVTIKSTYWVIPWELASYDNPNLFTAMILMSPLVNADAVSKLNLLAAKLMGTIT 60 Wyeth -------------MGATISILASYDNPNLFTAMILMSPLVNADAVSKLNLLAAKLMGTIT 47 Lister ---------MGHSMGATISILASYDNPNLFTAMILMSPLVNADAVSRINLLAAELMGTIT 51 **************************************** Cop PNAPVGKLCPESVSRDMDKVYKYQYDPLINHEKIKAGFASQVLHATNKVRKIISKINTPR 107 WR LNAPVGKLCPESVSRDMDKVYKYQYDPLINHEKIKAGFASQVLKATNKVRKIISKINTPR 120 Tian LNAPVGKLCPESVSRDMDKVYKYQYDPLINHEKIKAGFASQVLKATNKVRKIISKINTPR 120 Wyeth PNAPVGKLCPESVSRDMDKVYKYQYDPLINHEKIKAGFASQVLKATNKVRKIISKINTPP 107 Lister PNAPVGKLCPESVSRDMDKVYKYQYDPLINHEKIKAGFASQVLKATNKVRKIISKINTPP 111 *********************************************************** Cop LSYSREQTMRL-----VMFQVHIISCNMQIVIE-------------------------- 135 WR LSYSREQTIRL-----AMF---------------------------------------- 134 Tian LSYSREQTIRL-----AMF---------------------------------------- 134 Wyeth TLILQGINNEISDVLGAYYFMHANCNREIKIYEGAKHHLHKETDEVEKSVMKEIETWIF 167 Lister TLILQGTNNXISDVLGAYYFMHANCNREIKIYEGAEHELHKETDEVEKSVMKEIETWIF 171 Cop ---- WR ---- Tian ---- Wyeth NRVK 171 Lister NRVK 175 K6L CLUSTAL 0(1.2.4) multiple sequence alignment (SEQ ID NOS 578-581, respectively, appearance) Cop MSANCMFNLDNDYIYWKPITYPKALVFISHGAGKHSGRYDETAENISSLGILVISHDHIG 60 WR MSANCMFNIDNDYIYWKPITYPKALVFISHGAGKHSGRYDELAENISSLGILVFSHDHIG 60 Wyeth MSANCMFNLDNDYIYWKPITYPKALVFISHGAGKHSGRYDELAENISSLGILVFSHDHIG 60 Lister MSANCMFNLDNDYIIWKPITYPKALVFISHGAGKHSGRYDELAENISSLGILVFSHDHIG 60 ************************************************************ Cop HGRSNGEKMMIDDFGTARGNY 81 WR HGRSNGEKMMIDDFGTARGNY 81 Wyeth HGRSNGEKMMIDDFGTARGNY 81 Lister HGRSNGEKMMIDDFGTARGNY 81 ********************* K7R CLUSTAL 0(1.2.4) multiple sequence alignment (SEQ ID NOS 582-586, respectively, in  order of appearance) Cop MATKIDYEDAVFYFVDDDKICSRDSIIDLIDEYITWRNHVIVFNEDITSCGRLYKELMKF 60 WR MATKLDYEDAVFYFVDDDKICSRDSIIDLIDEYITWRNHVIVFNKDITSCGRLYKELMKF 60 Tian MATKLDYEDAVFYFVDDDKICSRDSIIDLIDEYITWRNHVIVFNKDITSCGRLYKELMKF 60 Wyeth MATKLDYEDAVFYFVDDDKICSRDSIIDLIDEYITWRNHVIVFNEDITSCGRLYKELMKF 60 Lister MATKLDYEDAVFYFVDDDKICSRDSIIDLIDEYITWRNHVIVINKDITSCGRLYKELMKF 60 ************************************************************ Cop DDVAIRYYGIDKINEIVEAMSEGDHYINFTKVHDQESLFATIGICAKITEHWGYKKISES 120 WR DDVAIRYYGIDKINEIVEAMSEGDHYINFTKVHDQESLFATIGICAKITEHWGYKKISES 120 Tian DDVAIRYYGIDKINEIVEAMSEGDHYINFTKVHDQESLFATIGICAKITEHWGYKKISES 120 Wyeth DDVAIRYYGIDKINEIVEAMSEGDHYINFTKVHDQESLFATIGICAKITEHWGYKKISES 120 Lister DDVAIRYYGIDKINEIVEAMSEGDHYINFTKVHDQESLFATIGICAKITEHWGYKKISES 120 ************************************************************ Cop RFQSLGNITDLMTDDNINILILFLEKKLN 149 WR RFQSLGNITDLMTDDNINILILFLEKKLN 149 Tian RFQSLGNITDLMTDDNINILILFLEKKLN 149 Wyeth RFQSLGNITDLMTDDNINTLILFLEKKLN 149 Lister RFQSLGNITDLMTDDNINTLILFLEKKLN 149 ***************************** F1L CLUSTAL 0(1.2.4) multiple sequence alignment (SEQ ID NOS 587-591, respectively, in  order of appearance) Cop MISMFMCNNIVDYVDDIDNGIVQDIEDEASNNVDHDYVYPLPENMVYREDKSTNILDYLS 60 WR MLSMFMCNNIVDYVDDIDNGIVQDIEDEASNNVDHDYVYPLPENMVYRFDKSTNILDYLS 60 Tian MLSMFMCNNIVDYVDDIDNGIVQDIEDEASNNVDRDYVYPIPENMVYRFDKSTNILDYLS 60 Wyeth MISMFMCNNIVDYVDDIDNGIVQDIEDEASNNVDHDYVYPLPENMVYRFDKSTNILDYLS 60 Lister MLSMFMCNNIVDYVDDIDNGIVQDIEDEASNNVDHDYVYPLPENMVYRFDKSTNILDYLS 60 **********************************:************************* Cop TERDHVMMAVRYYMSKQRLDDLYRQLPTKTRSYIDIINIYCDKVSNDYNRDMNIMYDMAS 120 WR TERDHVMMAVRYYMSKQRLDDLYRQLPTKIRSYIDIINIYCDKVSNDYNRDMNIMYDMAS 120 Tian TERDHVMMAVRYYMSKQRLDDLYRQLPTKTRSYIDIINIYCDKVSNDYNRDMNIMYDMAS 120 Wyeth TERDRVMMAVRYYMSKQRLDDLYRQLPTKTRSYIDIINIYCDKVSNDYNRDMNIMYDMAS 120 Lister TERDHVMMAVRYYMSKQRLDDLYRQLPTKTRSYIDIINIYCDKVSNDYNRDMNIMYDMAS 120 ************************************************************ Cop TKSFTVYDINNEVNTILMDNKGLGVRLATISFITELGRACMNPVKTIKMFTLLSHTICDD 180 WR TKSFTVYDINNEVNTILMDNKGLGVRLATISFITELGRACMNPVETIKMFTLLSHTICDD 180 Tian TKSFTVYDINNEVNTILMDNKGLGVRLATISFITELGRRUMNPVKTIKMFTLISHTICDD 180 Wyeth TKSFTVYDINNEVNTILMDNKGLGVRLATISFITKLGRACMNPVKTIKMFTLLSHTICDD 180 Lister TKSFTVYDINNEVNTILMDNKGLGVRLATISFITELGRACMNPVKTIKMFTLLSHTICDD 180 **********************************:*********:*************** Cop CFVDYITDISPPDNTIPNTSTREYLKLIGITALMFATYKTLKYMIG 226 WR YFVDYITDISPPDNTIPNTSTREYLKLIGITAIMFATYKTLKYMIG 226 Tian CFVDYITDISPPDNTIPNTSTREYLKLIGITALMFATYKILKYMIG 226 Wyeth CFVDYITDISPPDNTIPNTSTREYLKLIGITAIMFATYKTLKYMIG 226 Lister CFVDYITDISPPDNTIPNTSTREYLKIIGITAIMFATYKTLKYMIG 226 ********************************************** F2L CLUSTAL 0(1.2.4) multiple sequence alignment (SEQ ID NOS 592-596, respectively, in  order of appearance) Cop MFNMNINSPVREVEETNRAKSPTRQSPGAAGYDLYSAYDYTIPPGERQLIKTDISMSMIT 60 WR MFNMNINSPVREVKETNRAKSPTRQSPYAAGYDLYSAYDYTIPPGERQLIKTDISMSMPK 60 Tian MENMNINSPVRFVFETNRAKSPTRQSPGAAGYDLYSAYDYTIPPGERQLIKTDISMSMPK 60 Wyeth MENMNINSPVREVEETNRAKSPTRQSPGAAGYDLYSAYDYTIPPGERQLIKTDISMSMIT 60 Lister MFNMNINSPVRFVKETNRAKSPTRQSPGAAGYDLYSAYDYTIPPGERQLIKTDISMSMPK 60 ************************************************************ Cop ICYGRIAPRSGISLKGIDIGGGVIDEDYRGNIGVILINNGKCTFNVNTGDRIAQIIYQRI 120 WR FCYGRIAPRSGLSLKGIDIGGGVIDEDYRGNIGVILINNGKCTFNVNTGDRIAQLIYQRI 120 Tian ICYGRIAPRSGISLKGIDIGGGVIDEDYRGNIGVILINNGKCTFNVNTGDRIAQIIYQRI 120 Wyeth ICYGRIAPRSGISLKGIDIGGGVIDEDYRGNIGVILINNGKCTFNVNTGDRIAQIIYQRI 120 Lister FCYGRIAPRSGISLKGIDIGGGVIDEDYRGNIGVILINNGKCTENVNTGDRIAQIIYQRI 120 :*********************************************************** Cop YYPELEEVQSLDSTNRGDQGFGSTGLR 147 WR YYPELEEVQSLDSTNRGDQGFGSTGLR 147 Tian YYPELEEVQSLDSTDRGDQGFGSTGLR 147 Wyeth YYPELEEVQSLDSTNRGDQGFGSTGLR 147 Lister YYPELEEVQSLDSTNRGDQGFGSTGLR 147 **************:************ F3L CLUSTAL 0(1.2.4) multiple sequence alignment (SEQ ID NOS 597-601, respectively, in  order of appearance) Cop MPIEVNTVYCKNILALSMTKKEKTIIDAIGGNIIVNSTILKKISPYFRTHIRQKYTKNKD 60 WR MPIETNTVYCKNILALSMTKKEKTIIDAIGGNIIVNSTILKKISPYFRTHLRQKYTKNKD 60 Tian MPIEVNTVYCKNILALSMTKKEKTIIDAIGGNIIVNSTILKKISPYFRTHLRQKYTKNKD 60 Wyeth MPIEVNTVYCKNILAISMTKKEKTIIDAIGGNIIVNSTILKELSPYFRTHLRQKYTKNKD 60 Lister MPIFVNTVYCKNILAISMTKKERTIIDAIGGNSIVNSTILKKISPYFRTHLRQKYTKNKD 60 ************************************************************ Cop PVTRVCIDLDIHSLTSIVIYSYTGKVYIDSHNVVNLIRASILTSVEFIIYTCINFILRDF 120 WR PVTWVCIDLDIHSLTSIVIYSYTGKVYIDSHNVVNLIRASILTSVEFIIYTCINFILRDF 120 Tian PVTRVCIDLDIHSLTSIVIYSYTGKVYIDSHNVVNLIRASILTSVEFIIYTCINFILRDF 120 Wyeth PVTRVCIDLDIHSLTSIVIYSYTGKVYIDSHNVVNLIRASILTSVEFIIYTCINFILRDF 120 Lister PVTRVCIDIDIHSLTSIVIYSYTGKVYIDSHNVVNLIRASILTSVEFIIYTCINFILRDF 120 *** ******************************************************** Cop RKEYCVECYMMGIEYGLSNLICHTKNFIAKHFLELEDDIIDNFDYLSMKLILESDELNVP 180 WR RKEYCVECYMMGIEYGLSNLICHTKNFIAKHFLELEDDIIDNEDYLSMKLILESDELNVP 180 Tian RKEYCVECYMMGIEYGLSNLICHTKNFIARHFLELEDDIIDNEDYLSMEIILESDELNVP 180 Wyeth RKEYCVECYMMGIEYGLSNLICHTKNFIAEHFLELEDDIIDNEDYLSMKLILESDELNVP 180 Lister RKEYCVECYMMGIEYGLSNLICHTKNFIAEHFLELEDDIIDNEDYLSIKLILESDELNVP 180 ***********************************************:************ Cop DEDYVVDEVIEWYIKRRNKLGNILLLIKNVIRSNYLSPRGINNVKWILDCTKIFHCDKQP 240 WR DEDYVVDEVIEWYIKRANKIGNILLLIKNVIRSNYLSPRGINNVKWILDCTKIFHCDKQP 240 Tian DEDYVVDEVIEWYIKRANKIGNILLLIKNVIRSNYLSPRGINNVKWILDCTKIETCDKQP 240 Wyeth DEDYVVOFVIEWYIKRANKIGNILLLIKNVIRSNYLSPRGINNVKWILDCTKIFHCDKQP 240 Lister DEDYVVDFVINNYIKRRNKLGNLLLLIKNVIRSNYLSPRGINNVKWILDCTKIFHCDKQP 240 ************************************************************ Cop RKSYKYPFIEYPMNMDQIIDIFHMCTSTHVGEVVILIGGWMNNEIHNNAIAVNYISNNWI 300 WR RKSYKYPFIEYPMNMDQIIDIFHMCTSTHVGEVVILIGGWNNNEIHNNAIAVNYISNNWI 300 Tian RKSYKYPFIEYPMNMDQIIDIFHMCTSTHVGEVVYLIGGWNVNEIHNNAIAVNYISNNWI 300 Wyeth RKSYKYPFIEYPMFMDQIIDIFHMCTSTHVGEVVYLIGGWMNNEIHNNAIAVNYISNNWI 300 Lister RKSYKYPFIEYPMNMDQIIDIFHMCTSTHVGEVVYLIGGWMNNEIHNNAIAVNYISNNWI 300 ************************************************************ Cop PIPPMNSPRLYATGIPANNKLYVVGGLPNPTSVERWFHGDAAWVNMPSLLKPRCNPAVAS 360 WR PIPPMNSPRLYASGIPANNKLYVVGGLPNPTSVERWFHGDAAWVNMPSLLKPRCNPAVAS 360 Tian PIPPMNSPRLYASGIPANNKLYVVGGLPNPTSVERWFHGDAAWVNMPSLLKPRCNPAVAS 360 Wyeth PIPPMNSPRLYASGIPANNKLYVVGGLPNPTSVERWFHGDAAWVNMPSLLKPRCNPAVAS 360 Lister PIPPMNSPRLYASGIPANNKLYVVGGLPNPTSVERWFHGDAAWVNMPSLLKPRCNPAVAS 360 ************:*********************************************** Cop INNVIYVMGGHSETDTTTEYLLPNEDQWQFGPSTYYPHYKSCALVFGRRLFLVGRNAEFY 420 WR INNVIYVMGGHSETDTTTEYLLPNHDQWQFGPSTYYPHYKSCAIVFGRRLFLVGRNAEFY 420 Tian INNVIYVMGGHSETDTTTEYLLPNHDQWQFGPSTYYPHYKSCALVFGRALFLVGRNAEFY 420 Wyeth INNVIYVMGGHSETDTTTEYLLPNHDQWQFGPSTYYPHYKSCALVFGRRLFLVGRNAEFY 420 Lister INNVIYVMGGHSETDTTTEYLLPNHDQWQFGPSTYYPHYKSCALVFGRRLFLVGRNAEFY 420 ************************************************************ Cop CESSNTWTLIDDPIYPRDNPELIIVDNKLLLIGGFYRGSYIDTIEVYNHHTYSWNIWDGK 480 WR CESSNTWTLIDDPIYPRDNPELIIVDNKLLLIGGFYRESYIDTIEVYNHHTYSWNINDGK 480 Tian CESSNTWTLIDDPIYPRDNPELIIVDNKLLLIGGFYRESYIDTIEVYNHHTYSWNINDGK 480 Wyeth CESSNTWTLIDDPIYPRDNPELIIVDNKLLLIGGFYRESYIDTIEVYNHHTYSWNIWDGK 480 Lister CESSNTWTLIDDPIYPRDNPELIIVDNKLLLIGGFYRESYIDTIEVYNHETYSWNIWDGK 480 ************************************* ********************** B14R CLUSTAL 0(1.2.4)  multiple sequence alignment (SEQ ID NOS 602-605, respectively, in  order of appearance) Cop ------------------------------------------------------------ WR MDIFREIASSMEGENVFISPASISSVLTILYYGANGSTAEQLSKYVEKEENMDKVSAQNI 60 Tian ------------------------------------------------------------ Wyeth ------------------------------------------------------------ Cop ------------------------------------------------------------ WR SFKSINKVYGRYSAVFKDSFLRKIGDKFQTVDFTDCRTIDAINKCVDIFTEGKINPLLDE 120 Tian ------------------------------------------------------------ Wyeth ------------------------------------------------------------ Cop ---MNHCLLAISAVYFKAKWLTPFEKEFTSDYPFYVSPTEMVDVSMMSMYGELFNHASVK 57 WR PLSPDTCLLAISAVYFKAENLTPFEKEFTSDYPFYVSPTEMVDVSMNSMYGKAFNHASVK 180 Tian ---MNHCLLAISAVYFKAKWLTPFEKEFTSDYPFYVSPTEMVDVSMMSMYGKAFNHASVY 57 Wyeth ---MNHCLLAISAVYFKAEWLTPFEKEFTSDYPFYVSPTEMVDVSMMSMYGKAFNHASVK 57 : *********************************************: ******* Cop ESFGNFSIIELPYVGDTSMMVILPDKIDGLESIEQNLTOTNFKRWCNSLDAMFIDVHIPK 117 WR ESFGNFSIIELPYVGDTSMMVILPDKIDGLESIEQNLTDTNFKKWCNSLEATFIDVHIPK 240 Tian ESFGNFSIIELPYVGDTSMMVILPDKIDGLESIEQNLTDTNFKKWCDFMDAMFIDVHIPK 117 Wyeth ESIGNFSIIELPYVGDTSMMVILPDKIDGLESIEQNLTDTNFKKWCDFMDAMFIDVHIPK 117 Cop FKVTGSYNLVDTLVFSGLTEVFGSTGDYSNMCNLDVSVDAMIHKTYIDVNEEYTEAAAAT 177 WR FKVTGSYNLVDTLVKSGLTEVFGSTGDYSNMCNSDVSVDAMIEKTYIDVNEEYTEAAAAT 300 Tian FINTGSYNLVDTLVKSGLTEVFGSTGDYSNMCNLDVSVDAMIHKTYIDVNEEYTFAAAAT 177 Wyeth FKVTGSYNLVDTLVKSGLTEVFGSTGDYSNMCNLDVSVDAMIHKTYIDVNEEYTFAAAAT 177 ************************************************************ Cop CALVSDCASTITNEFCVDHPFIYVIRHVDGKILFVGRYCSPTTNC 222 WR CALVSDCASTITNEFCVDHPFIYVIREVDGKILFVGRYCSPTTNC 345 Tian CALVSDCASTITNEFCVDHPFIYVIRHVDGKILFVGRYCSPTTNC 222 Wyeth CALVSDCASTVTNEFCADHPFIYVIRHVDGKILFVGRYCSPTTNC 222 **********:*****.**************************** B15R CLUSTAL 0(1.2.4) multiple sequence alignment (SEQ ID NOS 606-610, respectively, in   order of appearance) Cop MTANFSTHVESPQHCGCDRITSIDDVXQCLTEYITASSIAYRNRQCAGQLYSTLLSERDD 60 WR MTANFSTHVESPQHCGCDRITSIDDVRQCLTEYIYWSSYAYANRQCAGQLYSTLLSFRDD 60 Tian MTANFSTHVESPQHCGCDRLTSIDDVXQCLTEYIYWSSYAYANRQCAGQLYSTLLSERDD 60 Wyeth MTANFSTHVESPQHCGCDRITSIDDVKQCLTEYITASSIAYRNRQCAGQLYSTLLSFRDD 60 Lister MTANFSTHVESPQHCGCDRITSIDDVKQCLTEYITASSYAYRNRQCAGQLYSTLLSFRDD 60 Cop AELVFIDIRELVKNMPWDDVKDCTEIIRCYIPDEQKTIREISAIIGLCAYAATYWGGEDH 120 WR AELVFIDIRELVKNMPWDDVKDCAEIIRCYIPDEQKTIREISAIIGLCAYAATYWGGEDH 120 Tian AELVFIDIRELVKNMEWDDVKDCTEIIRCYIPDEQKTIREISAIIGLCAYAATYWGGEDH 120 Wyeth AELVFIDIRELVKNMPWDDVKDCAEIIRCYIPDEQKTIREISAIIGLCAYAATYWGGEDH 120 Lister AELVFIDIRELVKNMPWDDVKDCTEIIRCYIPDEQKTIREISAIIGLCAYAATYWGGEDH 120 *************:*********:************************************ Cop PTSNSLNALFVMLEMLNYVDYNIIFRAMN 149 WR PTSNSLNALFVMLEMLNYVDYNIIFRAMN 149 Tian PTSNSINALFVMMEMLNYVDYNIIERRMN 149 Wyeth PTSNSLNALFVKLEMLNYVDYNIIERRMN 149 Lister PTSNSLNALEVKLEMLNYVDYNIIERRMN 149 ***************************** B ORF E CLUSTAL 0(1.2.4) multiple sequence alignment (SEQ ID NOS 611-612, respectively, in  order of appearance) Cop MINSSIHTPEYDVIIHVIEHLKHHKQCVQTVTSGMVETSPVSSSICTKSDDGRNISDGEL 60 Tian MYNSSIHTPEYDVIIHVIEHLKHHKQCVQTVTSGMVETSPVSSSICTKSDDGRNISDGEM 60 ************************************************************ Cop LIRYITTDDFCTIFDIIPRHIFYQLANVDEH 91 Tian LIRYITTDDFCTIFDIIPRHIFYQLANVDEH 91 ******************************* B16R CLUSTAL 0(1.2.4) multiple sequence alignment (SEQ ID NOS 613-617, respectively, in  order of appearance) Cop MSILPVIFLPIFFISSFVQTFNASECIDKGXYFASFMELENEPVILPCPQINTISSGYNI 60 WR MSILPVIELSIFFYSSFVQTFNAPECIDKGQYFASFMELENEPVILPCPQINTLSSGYNI 60 Tian ------------------------------------MELENEPVILPCPQINTLSSGYNI 24 Wyeth MSILPVIELSIFFYSSFVQTFNASECIDKGQYFASFMELENEPVILPCPQINTLSSGYNI 60 Lister MSILPVIFLPIFFYSSFVQTFNAPECIDKGQYFASFMELENEPVILPCPQINTLSSGYNI 60 *********************** Cop LDILWEKRGADNDRIIPIDNGSNMIIINPTQSDSGIYICITTNETYCDMMELNLTIVSVS 120 WR LDILWEKRGADNDRIIPIDNGSNMIILNPTQSDSGIYICITTNETYCDMMSLNLTIVSVS 120 Tian LDILWEKAGADNDRIIPIDNGSNMMILNPTQSDSGIYICITTNETYCDMMSLNLTIVSVM 84 Wyeth LDILWEKRGADNDRIIPIDNGSNMLILNPTQSDSGIYICITTNETYCDMMSLNLTIVSVS 120 Lister LDILWEKRGADNDRIIPIDNGSNMLILNPTQSDSGIYICITTNETYCDMMSLNLTIVSVS 120 ************************************************************ Cop ESNIDFISYPQIVNERSTGEMVCPNINAFIASNVNADIIWSGERRLANKRIKQRTPGIIT 180 WR ESNIDLISYPQIVNERSTGEMVCPNINAFIASNVNADIIWSGHRRLANKRLKQRTPGIIT 180 Tian ESNIDLISYPQIVNERSTGEMVCPNINAFIASNVNADIIWSGHARLANKRLKQRTPGIIT 144 Wyeth ESNIDLISYPQIVNERSTGEMVCPNINAFIASNVNADIIWSGHRRLANKRLKQRTPGIIT 180 Lister ESNIDLISYPQIVNERSTGEMVCPNINAFIASNVNADIIWSGHARLANKRIKQRTPGIIT 180 *****:****************************************************** Cop IEDVRKNDAGYITCVLEYIYGGKTYNVTRIVKLEVRDKIIHPTMQLPEGVVTSIGSNITI 240 WR IEDVEKNDAGYITCVLEYIYGGKTYNVTRIVKLEVRDKIIPSTMQLPDGIVISIGSNLTI 240 Tian IEDVRKNDAGYITCVLEYIYEGKTYNVTRIVKLEVRDKIIPSTMQLPDGIVTSIGSNLTI 204 Wyeth IEDVRKNDAGYYTCVLEYIYGGKTYNVTRIVKLEVRDKIIPSTMQLPDGIVISIGSNITI 240 Lister IEDVRKNDAGYITCVLEYIYRGKTYNVTRIVKLEVRDKIIPSTMQLPDGIVISIGSNITI 240 ******************** ******************* *****:*:********** Cop ACRVSLAPPTIDADVFWISNGMYYEEDDGDGDGRISVANKIYMTDKRRVITSRININPVX 300 WR ACRVSLAPPTTDADVFWISNGMYYEEDDGDGNGRISVANKIYMTDKRRVITSRLNINPVK 300 Tian ACAVSLAPPTTDADVFWISNGMYYEEDDGDGNGAISVANKIYMTDKAAVITSALNINPVE 264 Wyeth ACAVSLAPPTTDTDVFWISNGMYYEEDDGDGDGAISVANKIYMIDKAAVITSALNINPVK 300 Lister ACAVSLAPPTTDADVFWISNGMYYEEDDGDGNGRISVANKIYMTDKAAVITSAININPVK 300 ************:******************:**************************** Cop EEDATTFTCMAFTIPSISKTVTVSIT 326 WA EEDATTFTCMAFTIPSISKTVTVSIT 326 Tian EEDATTFTCMAFTIPSISKTVTVSI- 289 Wyeth EEDATTFTCMAFTIPSISKTVTVSIT 326 Lister EEDATTFTCMAFTIPSISKTVTVSIT 326 ************************** B ORF F CLUSTAL 0(1.2.4) multiple sequence alignment (SEQ ID NOS 618-619, respectively, in  order of appearance) Cop MVIIPGVRCISLLFLARACPLHIISAFTLLAINALILGHTISPVDISFTICGYEIKSIFD 60 Tian MVIIPGVACLSLLFLAARCPLHIISAFTLLAINALILGHTISPVDLSFTICGYEIRSIFD 60 *******************************************************:**** Cop SETDTIVAFNDIMSQ 75 Tian SKTDTIVKFNDIMSQ 75 *:************* B17L CLUSTAL 0(1.2.4) multiple sequence alignment (SEQ ID NOS 620-624, respectively, in   order of appearance)  Cop MSAKFMQVYEYDREQYLDEFIEDAYNDSFITSPEYYSAEKYMCAYTTINHNCVNVRACAL 60 WR MSAKFMQYEYDREQYYLDEFIEDAYNDSFITSPEYYSAEKYMCAYTTINHNCINVARCAL 60 Tian MSRKFMQVYEYDREQYLDEFIEDAYNDSFITSPEYYSAEKYMCAYTTLNHNCVNVRACAL 60 Wyeth MSAKFMQVYEYDREQYLDEFIEDAYNDSFITSPEYYSAEKYMCAYTTLNUNCVNVARCAL 60 Lister MSAKFMONYEYDREQYLDEFIEDAYNDSFITSPEYYSAEKYMCAYTTINHNCINVRACAL 60 ****************************************************:******* Cop DSKLIHDIITNCKIYNNIELVAATKFVYYLDLIKCNWVSKVGDSVIYAVIFITHTSTRNL 120 WR DSKILHDIITNCKIYNNIELVAATKFVYYLDLIKCNWVSKVGDSVLYAVIFITHTSTANL 120 Tian DSKILHDIITNCKIYNNIELVAATKFVYYLDLIKCNWVSKVGDSVLYPVIFITHTSTANL 120 Wyeth DSKLLHDIITNCKIYNNIELVAATKFVYYLDLIKCNWVSKVGDSVLYPVIFITHTSTANL 120 Lister DSKLLHDIITNCKIYNNIELVAATKFVYYLDLIKCNWVSKVGDSVLYPVIFITHTSTANL 120 ************************************************************ Cop DKVSVKTYKGVKVKKINACADHAIVINPFVAFKITLANKTSHAINIVTFCKLATDITAVE 180 WR DKVSVKTYKGVAVKKLNACADHAIVINPFVKFKITLANKTSHAINIVTFCKLKTDITAVE 180 Tian DKVSVKTYKGVKVAELNACADHAIVINPFVKFKITLANKTSHAEVIVTFCKLRTDITQIE 180 Wyeth DKVSVKTYKGVKVKKINACADHAIVINPFVAFKLTIPNKTSHAKVIVTFCKLRTDITQIE 180 Lister DKVSVATYKGVAVKKINRCADHAIVINPFVKFKITLPNRTSHARVINTFCKLRTDITQIE 180 ****************************************************:**** :* Cop APLAGNVIVYTFADINKAIAGYIHVNIEGCIDGMIYINSSKFACVIKLHASMYRIPPFPI 240 WR APLAGNVIVYTFADINKAIAGYIHINIEGCIDGMIYINSSKFACVLKIHRSMYRIPPFPI 240 Tian APLSGNVIVYTFPNINKAIAGYIHVNIEGCIDGMIYINSSKFACVIKLHASMYRIPPFPI 240 Wyeth AFISGNVIVYTFADINKAIAGYIHVNIEGCIDGMIYINSSKFACVLKLHASMFAIPPFPI 240 Lister APLSGNVINYTIPDINKRIPGYTHVNIEGCIDGMIYINSSKFACVLKLHASMYRIPPFPI 240 *** *********:**********:*********************************** Cop DICSCCSQYTNDDIEIPIHDLIKDVAIFANAETVYYLKINNKTIAAFTYFENIDTAITQE 300 WR DICSCCSQYINYDIEIPIHDLIKDVAIFKNKETVYYLKLNNKTIAAFTYFNNIDTAITQE 300 Tian DICSCCSQYTNGDIEIPIHDLIKDVAIFKNKETVYYLKLNNKTIARFTYFNNIDTAITQE 300 Wyeth DICSCCSQYTNDDIEIPIHDLIKDVAIFKNKETVYYLKLNNKTIAAFTYFNNIDTAITQE 300 Lister DICSCCSOYTNDDIEIPIHDLIKDVAIFKNKETVYYLKINNKTIAAFTYFNNIDTAITQE 300 ********* * ************************************************ Cop HEYVKIALGIVCKLMINNMHSIVGVNHSNTFVNCLLEDNV 340 WR HEYVKIALGIVCKLMINNMHSIVGVNHSNTFVNCLLEDNV 340 Tian HEYVKIALGIVCKLMINNMHSIVGVNRSNTFVNCLLEDNV 340 Wyeth HEYVKIALGIVCKLMINNMHSIVGVNHSNTFVNCLLEDNV 340 Lister HEYVKIALGIVCKLMINNMHSIVGVNHSNTFVNCLLEDNV 340 **************************************** B18R CLUSTAL 0(1.2.4) multiple sequence alignment (SEQ ID NOS 625-628, respectively, in  order of appearance) Cop MSRRLIYVLNINRKSTHKIQENEIYTYFSHCNIDHTSTELDFVVKNYDLNRRQHVTGYTA 60 WR MSRRLIYVLNINRESTHKIGENEIYTYFSHCNIDHTSTELDFVVKNYDLNRRQPVTGYTA 60 Tian MSRRLIYVLNINRESTHKIQENEIYTYFSHCNIDHTSTELDFVVKNYDLNRRHPVTGYTA 60 Wyeth MSRRLIYVLNINRESTHKIQENEIYTYFSHCNIDHTSTELDFVVKNYDLNRRQPVTGYTA 60 *************:**************************************: ****** Cop LHCYLYNNYFTNDVIKILLNHDVNVTMETSSGRMPVYILLTRCCNISHDVVIDMIDKDKN 120 WR LHCYLYNNYFTNDVLKILLNHGVDVIMKTSSGRMPVYILLTRCCNISHDVVIDMIDKDEN 120 Tian LHCYLYNNYFTNDVLKILLNHGVDVTMETSSGRMPVYILLTRCCNISHDVVIDMIDKDKN 120 Wyeth LHCYLYNNYFTNDVLKILLNHGVDVTMETSSGRMPVYILLTRCCNISHDVVIDMIDKDKN 120 *********************.*:************************************ Cop HISHRDYSNLLLEYIKSRYMILKEEDIDENIVSTLIDKGIDPNETQDGYTALHYYYLCLA 180 WR HLIHRDYSNILLEYIKSRYMILKEEDIDENIVSTILDKGIDPNFKQDGYTALHYYYLCLA 180 Tian HLLHRDYSMILLEYIKSRYMILKEEDIDENIVSTILDKGIDPNETQDGYTALHYYYLCLA 180 Wyeth HLSHRDYSNILLEYIKSRYMLIKEEDIDENIVSTLLDKGIDPNFKQDGYTALHYYYLCLA 180 ** ********************************************************* Cop HVYKPGECRKPITIKKAKRIISIFIQHGANINALDNCGNTPFHLYLSIEMCNNIHMTKMI 240 WR HVYKPGECRKPITIKEAKRIISIFIQHGANINALDNCONTPFHLYLSIEMCNNIHMTKMI 240 Tian HVYKPGECRKPITIKKAKRIISIFIQHGANLNALDNCONTPFHLYLSIEMCNNIHMTKMI 240 Wyeth HVYKPGECRKPITIKKAKRIISLFIQHGANINALDNCGNTPFHLYLSIEMCNNIHMTKMI 240 ************************************************************ Cop LTFNPNFKICNNHGLTPILCYITSDYIQHDILVMLIHHYETNVGEMPIDERRMIVFEFIK 300 WR LTFNPNFEICNNHOLTPILCYITSDYIQHDILVMLIHHYETNVGEMPIDERRIIVFEFIK 300 Tian LTFNPNFKICNNHGLTPILCYITSDYIQHDILVMLIHHYETNVGEMPIDERRIIVFEFIK 300 Wyeth LTFNPNFKICNNHGLTPILCYITSDYIQHDILVMLIHRYETNVGEMPIDERRIIVFEFIK 300 *******:*********************************************:****** Cop TYSTRPADSITYLMNRFKNINIYTRYEGKTLIHVACEYNNTQVIDYLIRINGDINALTDN 360 WR TYSTRPADSITYLMNRFKNIDIYTRYEGKTILHVACEYNNTHVIDYLIRINGDINALTDN 360 Tian TYSTRPADSITYLMNRFKNINIYTRYEGKTILHVACEYNNTQVIDYLIRINGDINALTDN 360 Wyeth TYSTRPADSITYLMNRFKNINIYTRYEGKTILHVACEYNNTHVIDYLIRINGDINALTDN 360 ******************:**********************:****************** Cop NKHATQLIIDNKENSPYTINCLLYILRYIVDKNVIRSLVDQLPSLPIFDIKSFEKFISYC 420 WR NKHATQLIIDNKENSPYTINCLLYILRYIVDENVIRSLVDQLPSLPIFDIKSFEKFISYC 420 Tian NKHATQLIIDNKENSPYTINCLLYILRYIVDKNVIRSLVDOLPSLPIFDIKSFEKFISYC 420 Wyeth NKHAIQLIIDNKENSPYTIDCLLYILRYIVDKNVIRSLVDQLPSLPIFDIKSFEKFISYC 420 **** **************:**************************************** Cop ILLDDTFYDRHVENRDSKTYRYAFSKYMSFDKYDGIITKCHDETMILKLSTVLDTTLYAV 480 WR ILIDDTFYNRHVENRDSKTYRYAFSKYMSFDKYDGIITKCHKETILLKISTVLDTTLYAV 480 Tian ILLDDTFYDRHVENRNSKTYRYAFSKYMSFDKYDGIITKCHDETMLLKISTVIDTTLYAV 480 Wyeth ILIDDTFYNRHVENRNSKTYRYAFSKYMSFDKYDGIITKCHDETMILKLSTVLDTTLYAV 480 ********:***:**:*************************.**:*************** Cop LRCHNSRKLARYLTELKKYNNDKSFKIYSNIMNERYLNVYYKDMYVSKVYDKLFPVFTDK 540 WR LACHNSKKIRRYLTELKKYNNDKSFKIYSNIMNERYLNVYYKDMYVSKVYDKLFPVETDK 540 Tian LACHNSRKLARYLTELKKYNNDKSFKIYSNIMNERYLNVYYKDMYVSKVYDKLFPVFTDK 540 Wyeth LRCHNSKKLRRYLNELKKYNNDKSFKIYSNIMNERYLNVYYKDMYVSKVYDKLFPVFTDK 540 ******:******.********************************************** Cop NCLITLLPSEIIYEILYMITINDLYNISYPPTIN 574 WR NCLITILPSEIIYEILYMITINDLYNISYPPTKV 574 Tian NCLLTLLPSEIIYEILYMITINDLYNISYPPTKV 574 Wyeth NCLITLIPSEIIYEILYMLTINDLYNISYPPTKV 574 ---------------------------------- B19R CLUSTAL 0(1.2.4) multiple sequence alignment (SEQ ID NOS 629-632, respectively, in  order of appearance) Cop MTMKMMVHIYFVSLSLLLLLFHSYAIDIENEITEFFNKMRDTLPAKDSKWLNPACMFGGT 60 WR MTMKMMVHIYFVL--LLLLLFHSYAIDIENEITEFFNKMRDTIPAKDSKWLNPACMFGGT 58 Tian MTMKNMVYIYFVSLSLLLLLFHSYAIDIENEITEFFNKMRDTLPAKDSKWLNPACMFGGT 60 Wyeth MTMKMMVHIYFVSLSLLLLLFHSYAIDIENEITEFFNKMRDTLPAKDSKWINPACMFGGT 60 ************** ********************************************* Cop MNDMATLGERFSAKCPPIEDSLLSHRYKDYVVKWERLEKNARRQVSNKRVNEGDLWIANY 120 WR MNDIAALGEPFSAKCPPIEDSLLSHRYKDYVVXWERLEKNARRQVSNKRVKHGDLWIANY 118 Tian MNDIAALGEPFSANCPPIEDSLLSHRYKDYVVKWERLEKNRRRQVSNERVEHGDLWIANY 120 Wyeth MNDIATLGEPFSAKCPPIEDSLLSERYKDYVVKWERLEKNRRRQVSNKRVENGDLWIANY 120 ***:*:****************************************************** Cop TSKESNRRYLCTVTTKNGDCVOGIVRSHIKEPPSCIPKTYELGTHDKYGIDLYCGILYAK 180 WR TSKESNRRYLCTVTTENGDCVQGIVRSHIREPPSCIPKTYELGTHDKYGIDLYCGILYAK 178 Tian TSEFSNRRYLCTVTTRNGDCVQGIVRSHIKEPPSCIPKTYELGTHDKYGIDLYCGILYAK 180 Wyeth TSKESNRRYLCTVTTKNGOCVQGIVRSHIRKPPSCIPKTYELGTHDKYGIDLYCGILYAK 180 *****************************:****************************** Cop HYNNITWYKDRKEINIDDIKYSOTGKELIIHNPELEDSGRYDCYVHYDDVRIKNDIVVSR 240 WR HYNNITWYKDNEEINIDDIKYSQTGKELIIHNPELEDSGRYDCYVHYDDVRIKNDIVVSR 238 Tian HYNNITWYKDRKEINIDDIKYSQTGKELIIHNPELEDSGRYDCYVEYDDVRIENDIVVSR 240 Wyeth HYNNITWYKDRKEINIDDIKYSQTGKKLIIHNPELEDSGRYDCYVHYDDVRIENDIVVSR 240 **************************:********************************* Cop CKILTVIPSQDHREKLILDPKINVTIGEPANITCTAVSTSLLIDDVLIEWENPSGWLIGF 300 WR CKILTVIPSQDHRFKLILDPKINVTIGEPANITCTAVSTSLLIDDVLIEWENPSGWLIGF 298 Tian CKILTVIRSQDHRFKLILDPKINVTIGEPANITCTAVSTSLLIDDVLIEWENPSGWLIGF 300 Wyeth CKILVTVIPSQDHRFKLKRNCGYASN---------------------------------- 265 ***************** : . Cop DEDVYSVLTSRGGITEATLYFENVTEEYIGNTYNCRGHNYYFEKTLTTTVVLE 353 WR DEDVYSVITSRGGITEATLYFENVTEEYIGNTYKCRGENYYFEKTLTTTVVLE 351 Tian DEDVYSVITSRGGITEATLYFENVTEEYIGNTYKCRGENYYREKTLTTTVVIE 353 Wyeth ----------------------------------------------------- B21R CLUSTAL 0(1.2.4) multiple sequence alignment (SEQ ID NOS 633-634, respectively, in  order of appearance) Cop MSLESFIITTFNNNSSTNIDNMCHLYVKVCPSSILFRLETECCDINKLVEGTTPLHCYLM 60 Wyeth MSLESFIITTFNNNSSTNIDNMCHLYVKVCPSSLLFRIFVECCDINELVEGTTPLHCYLM 60 ************************************************************ Cop NEGFESSVLKNLIKEYVMNTFNVHDIHYTNI 91 Wyeth NEGFESSVLMNLLKEYVMTSITQIFNS---- 87 *******************.::.  B22R CLUSTAL 0(1.2.4) multiple sequence alignment (SEQ ID NOS 635-637, respectively, in  order of appearance) Cop MISLSFLIHNPLEKWKLKPSISINGYRSTFTMAFPCAQFRPCHCHATKDSLNTVADVREC 60 Wyeth MISLSFLIHNPLKKWKLKPSISINGYRSTFTMAFPCAQFRPCHCHATKDSLNTVADVRHC 60 Lister ----------------------------- MASPCAKFRPCHCHATKDSLYTVADVRIIC 29 ** ***:*********************** Cop LTEYILWVSHRWTHRESAGSLYRLLISFRTDATELFGGELKDSLPWDNIDNCVEIIKCEI 120 Wyeth LTEYILWVSHRWTHRETAGPLYRLLISFRTDATELEGGELKDSLPWDNIDNCVEIIKCEI 120 Lister LTEYILWVSHRWTHRESAGSLYRLLISFRTDATELFGGELKDSLPWD---NCVEIIKCFI 86 ****************:** *************************** ********** Cop RNDSMKTAEELRAIIGLCTQSAIVSGRVFNDKYIDILLMLRKILNENDYLTLLDHIRTAK 180 Wyeth RNDSZECAEELRAIIGLCTQSAIVSGRVFNDKYIDILLMCRKILNENDYLTLLDHIRTAK 180 Lister RNDSMKTAEELRAIIGLCTOSAIVSGRVFNDKYIDILLMLRKILNENDYLTLLDHIRTAK 146 ************************************************************ Cop Y 181 Wyeth Y 181 Lister Y 147 * B23R CLUSTAL 0(1.2.4) multiple sequence alignment (SEQ ID NOS 638-639, respectively, in  order of appearance) Cop MIAFIIFREIGIISTRIAMDYCGRECTILCRLLDEDVTYKKIKLEIETCHNLSKHIDRRG 60 Wyeth MIAFIIFREIGIISTRIAMDCT----CILCRLLDEDVTYKKIKLEIETCHNLSKHIDRRG 56 ******************** ********************************* Cop NNALHCYVSNKCDTDIKIVALLLSRGVERLCRNNEGLTPLGAYSKHRYVKSQIVHILISS 120 Wyeth NNALHCYVFNKCDTDIKIVRLLLSRGVERLCANNEGLTPLGVYSKHRYVKSQIVHLLISS 116 ******** ********************************.****************** Cop YSNSSNELKSNINDFDLSSDNIDLALLKYLIVDKRIRPSKNTNYAINGLGLVDIYVTTPN 180 Wyeth YSNSSNELKSNINDFDLSSDNIDLALLKYLIVDKRIRPSKRTNYAINSLGLVDIYVTTPN 176 ***********************************************.************ Cop PRPEVLLWLLKSECYSTGYVESTCMYNSDMCKNSLHYYISSHRESQSLSKDVIKCLINNN 240 Wyeth PRPEVLLWLLKSECYSTGYVFRTCMYNSDMCKNSLHYYISSHRESQSLSKDVIKCLINNW 236 ************************************************************ Cop VSIHGRDEGGSLPIQYYWSFSTIDIEIVKILLIKDVDTCRVYDVSPILEAYYLNKRFRVT 300 Wyeth VSIHGRDEGGSLPIQYYWSFSTIDIEIVKLLLIKDVDTCRVYDVSPILEAYYLNKRFRVT 296 ************************************************************ Cop PYNVDMEIVNLLIERRHTLVDVMRSITSYDSREYNHYTIDNILKRFRQQDESIVQAMLIN 360 Wyeth PYNVDMEIVNLLIERRHTLVDVMRSITSYDSREYNHYIIDNILKRFRQQDESIVQAMLIN 356 ************************************************************ Cop YLHYGDMVVRCMLDNGQQLSSARLLC 386 Wyeth YLHYGDMVVRCMLDNGQQLSSARLLC 382 ************************** B24R CLUSTAL 0(1.2.4) multiple sequence alignment (SEQ ID NOS 640-641, espectively, in  order of appearance) Cop MYGLILSRFNNCGYHCYETILIDVFDILSKYMDDIDMIDNENKTLLYYAVDVNNIQFAKR 60 Wyeth MYGLILSRENNCGYHCYETILIDVFDILSKYMDNIDMIDNENKTLLYYAVDVNNIQFAKR 60 *********************************:************************** Cop LLEYGASVTTSRSIINTAIQKSSYQRENKTRIVDLLLSYHPTLETMIDAFNRDIRYLYPE 120 Wyeth LLEYGASVTTSRSIINTAIQKSSYRRENKTKLVDLLLSYHPTLETMIDAFERDIRYLYPE 120 ************************:*****::**************************** Cop PLFACIRYALILDDDETSKVSMISPVIIRN------------------------------ 150 Wyeth PLFACIRYALILDDDFPSKVKYDISGRHKELKRYRVDINRMKNAYISGVSMFDILFKRSK 180 ********************. :: Cop ------------------ Wyeth RHRLRYAKNPTSNGTKKN 198 B25R CLUSTAL 0(1.2.4) multiple sequence alignment (SEQ ID NOS 642-644, respectively, in  order of appearance) Cop MBRINITKKIYCSVFLFLFLFLSYISNYEKVNDEMYEMGEMDEIVSIVRDSMWYIPNVFM 60 WR ----------------------------------------MDEIVRIVRDSMWYIPNVFM 20 Wyeth MBRINITKKIYCSVFLF--LFLSYISNYEKVNDEMYEMGEMDEIVSIVRDSMWYIPNVFM 58 ***** ************** Cop DDGKNEGHVSVNNVCHMYFTFFDVDTSSHLFKLVIKHCDLNKRGNSPLHCYTMNTRFNPS 120 WR DDGKNEGHVSVNNVCHMYFTFFDVDTSSHLFKLVIKHCDLNKRGNSPLHCYTMNTRFNPS 80 Wyeth DDGKNEGHVSVNNVOMMYFTFEDVDTSSHLFKLVIKHCDLNKRGNSPLHCYTMNTRFNPS 118 ************************************************************ Cop VLKILLHHOMRNFDSKDEKGHHYLIHSLSIDNKIFDILTDTIDDFSKSSDLLLCYLRYKF 180 WR VLKILLHHGMANFDSKDEKGHHYQSITRSLIY---------------------------- 112 Wyeth VLKILLHHGMRNFDSKD---DHYQSITRSLIY---------------------------- 147 ***************** .** : *:  Cop NGSLNYYVLYKGSDPNCADEDELTSLHYYCKHISTFYKSNYYKLSHTFMRAEKRFIYAII 240 WR ------------------------------------------------------------ Wyeth ------------------------------------------------------------ Cop DYGANINAVTHLPSTVYQT 259 WR ------------------- Wyeth  ------------------- B26R CLUSTAL 0(1.2.4) multiple sequence alignment (SEQ ID NOS 645-648, respectively, in  order of appearance) Cop MEQTLTRLETYLQQYTKHSPRVVYALLSRGYVIILIVITSWNDCATGHILIMLINWEEQK 60 WR -------------------MIFYLEEPIRGYVIILIVEPSWNDCATCHILIMILNWHEQK 41 Wyeth MEQTLTRLETYLQQYTKHSPRVVYALLSRGYVIILIVITSWNDCATGHILIMLLNWHEQK 60 Lister MEQTLTRUITYLQQYTKHSPRVVYALLSRGYVIILIVHPSWNDCATGHILIMLINWEEQK 60 . ******************************** Cop EEGQHLLYLFIKENQGYTLNILRYLLDRFDIQKDEYIYRLSEL----------------- 103 WR EEGQHLLYLFIKHNQGYTLNILRYLLDREDIQKDEYYNTAFQNCNNNVASYIGYDINLPT 101 Wyeth EEGQHLLYLFIKHNQGYTLNILRYLLDRFDIQKDEYYNTAFQNCNNNVASYIGYDINLPT 120 Lister EEGQHLLYLFIKENQGYTLNILRYLLDREDIQKDEYYNTAFQNCNNNVASYIGYDINLPT 120 ************************************ : Cop -------- WR KDGIRLGV 109 Wyeth KDGIRLGV 128 Lister KDGIRLGV 128 B27R CLUSTAL 0(1.2.4) multiple sequence alignment (SEQ ID NOS 649-652, respectively, in  order of appearance) Cop MLPHTSDTTSTFRLKTVEDLVFENRNIIYKADVVNDIIKHRLKVSLPMIKSLKYKMSEFS 60 WR MLPHTSDTTSTFRLKTVEDLVFENRNITYKADVVNDIIHHRLKVSLPMIKSLEYKMSLPT 60 Wyeth MLPHTSDTTSTFRLKTVFDLVFENRNITYKADVVNDIIHHRLK--VPMIKSLEYKMSEFS 58 Lister MLPHTSDTTSTFRLKTVEDLVFENRNITYKADVVNDIIHHRLKVSLPMIKSLEYMKSLPT 60 ******************************************* :********* : Cop PYDDYYVKKILAYCLLRDESFAELHSKFCLNEDYKSVFMKNISETKIDSIIVT 113 WR TITT------------------------------------------------- 64 Wyeth PYDDYYVKKILAYCLLRDESFAELKSKFCLNEDYKSVFMKNISEDKIDSIIVT 111 Lister TITT------------------------------------------------- 64 B28R CLUSTAL 0(1.2.4) multiple sequence alignment (SEQ ID NOS 653-655, respectively, appearance) Cop MKSVLYSYILFLSCIIINGRDIAPHAPSDGKCKDNEYKRENLCPGTYASALCDSKTNTQC 60 WR MKSVLYSYILELSCIIINGRDIAPHAPSDGKCKDNEYKRENLCPGTYASRLCDSKTNTQC 60 Wyeth -----------------------MHHPMESVKTTN--TNAIICV---REHTLPDYANTQC 32 * * :. . * .. :* .: . :**** Cop TPCGSGTETSRNNKLPACLSCNGRADPVTLLTIESVNALPDIIVFSKDHPDARHVFPKQN 120 WR TPCGSGTFTSRNNHLPACLSCNGRRDRVTRLTIESVNALPDIIVFSKDHPDARHVFPKQN 120 Wyeth TPCGSGTFTSANNELPACLSCNGRRDRVTLLTIESVNALPDIIVFSKDHPDARHVFPKQN 92 ***************************** ****************************** Cop VE 122 WR VE 122 Wyeth V- 93 * C23L/B29R CLUSTAL 0(1.2.4) multiple sequence alignment (SEQ ID NOS 656-660, respectively, in  order of appearance) Cop --------------MEVPASLQQSSSSSSSCTEEENKEHMGIDVIIKVTKQDQTPTNDKI 46 WR --------------MEVPASLQQSSSSSSSCTEEENKHEMGIDVIIKVTKQDQTFINDKI 46 Tian --------------MEVPASLQQSSSSSSSCTEEENKHHMGIDVIIINTKQDQTPTNDKI 46 Wyeth --------------MEVPASLQQ---SSSSCTEEENKEHMGIDVIIKVTKQDQTPINDKI 43 Lister MKQYIVLACMCLAAAAMPASLQQSSSSSSSCTEEENKHEMGIDVIIKVTKQDQTFINDKI 60 :****** ********************************** Cop CQSVTEITESESDPDPEVESEDDSTSVEDVDPPITYYSIIGGGLRMNFGETKCPQIKSIS 106 WR CQSVTEITESESDPDPEVESEDDSTSVEDVDPPITYYSIIGGGLRMNFGETKCPQIKSIS 106 Tian CQSVTEITESESDPDPEVESEDDSTSVEDVDPPTTYYSIIGGGIRMNFGFTKCPQIKSIS 106 Wyeth CQSVTEITESESDPDPEVESEDDSTSVEDVDIPTTYYSIIGGGIRMNFGETKCPQIKSIS 103 Lister CQSVTEITESESDPDPEVESEDDSTSVEDVDPPITYYSIIGGGLRMNFGETKCPQIKSIS 120 ******************************* **************************** Cop ESADGNTVNARLSSVSPGQGKDSPAITREEALAMIKDCEVSIDIRCSEEEKDSDIKTHPV 166 WR ESADGNTVNARLSSVSPGQGKDSPAITHEEALAMIEDCEVSIDIRCSEEEKDSDIKTHPV 166 Tian ESADGNTVNARLSSVSPGQGKDSPAITHEEALAMIKDCEVSIDIRCSEEEKDSDIKTHPV 166 Wyeth ESADGNTVNARLSSVSPGQGKDSPAITHEEALAMIKDCEVSIDIRCSEEEKDSDIKTHPV 163 Lister ESADGNTVNARLSSVSPGQGKDSPAITHEEALAMIKDCEVSIDIRCSEEEKDSDIKTHPV 180 ***************************:******************************** Cop LGSNISHKKVSYEDIIGSTIVDTKCVKNLEFSVRIGDMCKESSELEVEDGFKYVDGSASE 226 WR LGSNISHKKVSYEDIIGSTIVDTKCVKNLEFSVRIGDMCKESSELEVXDGFKYVDGSASE 226 Tian LGSNISHKKVSYEDIIGSTIVDTKCVENLEFSVRIGDMCKESSELEVEDGFEYVDGSASE 226 Wyeth LGSNISHKKVSYEDIIGSTIVDTKCVKNLEFSVRIGDMCKESSELEVKDGEKYVDGSASE 223 Lister LGSNISHKEVSYEDIIGSTIVDTKCVKNLEFSVRIGDMCKESSELEVEDGEKYVDGSASE 240 ************************************************************ Cop GATDDTSLIDSTKLEACV 244 WR GATDDTSLIDSTKLEACV 244 Tian GATDDISLIDSTKLKACV 244 Wyeth GATDDISLIDSTKIKACV 241 Lister GATDDTSLIDSTKLEACV 258 ******************

Assays for Measuring Virus Characteristics

Assays known in the art to measure the tumor spreading and virulence of a virus include but are not limited to measuring plaque size, syncytia formation, and/or comet assays (EEVs). Assays known in the art to measure the immunostimulatory activity of a virus include but are not limited to NK activation (measured in % CD69 expression), NK degranulation (measured in fold increase of CD107a), and/or T-cell priming assays. Assays known in the art to measure the selectivity of a virus include, but are not limited to, tail pox lesions, biodistribution, and/or body mass measurements.

Examples of Proteins Encoded by Orthopoxvirus Genes

Exemplary proteins encoded by orthopoxvirus genes described in this disclosure are reproduced below in Tables 31-40. As used below, the term “location” refers to the location of the gene with respect to the deleted nucleic acids in exemplary orthopoxvirus vectors described herein. For various genes, amino aid sequence information and protein accession ID numbers are provided.

TABLE 31 Examples of proteins encoded by Copenhagen Vaccinia genes deleted in CopMD5p vector SEQ ID Protein NO. Gene Accession ID Amino Acid Sequence Location SEQ ID C2L AAA47999.1 MESVIFSINGEIIQVNKEIITASPYNFFKRIQDHHLKD Inside NO:23 (26% 5′)  EAILNGINYHAFESLLDYIRWKKINITINNYEMILVA Deletion AIIIDVPPVVDLCVKTMIHNINSTNCIRMFNFSKRYGI KKLYNASMSEIINNITAVISDPEFGKLSKDELTTILS HENVNVNHEDVTAMILLKWIHKNPNDVDIINILHPK FMTNTMRNAISLLGLTISKSTKPVTRNGIKHNIVVIK NSDYISTITHYSPRTEYWTIVGNTDRQFYNANVLHN CLYIIGGMINNRHVYSVSRVDLETICKWKTVTNMSS LKSEVSTCVNDGKLYVIGGLEFSISTGVAEYLKHGT SKWIRLPNLITPRYSGASVFVNDDIYVMGGVYTTYE KYVVLNDVECFTKNRWIICKSPMPRHHSIVYAVEYD GDIYVITGITHETRNYLYKYIVKEDKWIELYMYFNH VGKMFVCSCGDYILIIADAKYEYYPKSNTWNLFDM STRNIEYYDMFTKDETPKCNVTHKSLPSFLSNCEKQ FLQ SEQ ID C1L AAA48000.1 MVICNNKISNSCRMIMSTNPNNILMRHLKNLTDDEF Inside NO:24 KCIIHRSSDFLYLSDSDYTSITKETLVSEIVEEYPDDC Deletion NKILAIIFLVLDKDIDVDIETKLKPKPAVRFAILDKM TEDIKLTDLVRHYFRYIEQDIPLGPLFICKIDSYRTRAI NKYSKELGLATEYFNKYGHLMFYTLPIPYNRFFCRN SIGFLAVLSPTIGHVKAFYKFIEYVSIDDRRKFKKEL MSK SEQ ID N1L AAA48001.1 MRTLLIRYILWRNDNDQTYYNDDFKKLMLLDELVD Inside NO:25 DGDVCTLIKNMRMTLSDGPLLDRLNQPVNNIEDAK Deletion RMIAISAKVARDIGERSEIRWEESFTILFRMIETYFDD LMIDLYGEK SEQ ID N2L AAA48002.1 MTSSAMDNNEPKVLEMVYDATILPEGSSMDPNIMD Inside NO:26 CINRHINMCIQRTYSSSIIAILNRFLTMNKDELNNTQ Deletion CHIIKEFMTYEQMAIDHYGEYVNAILYQIRICRPNQH HTIDLFICKIKRTPYDTFKVDPVEFVICKVIGFVSILNK YKPVYSYVLYENVLYDEFKCFINYVETKYF SEQ ID MIL AAA48003.1 MIFVIESKLLQIYRNRNRNINFYTTMDNIMSAEYYLS Inside NO:27 LYAKYNSKNLDVFRNMLQAIEPSGNNYHILHAYCG Deletion IKGLDERFVEELLHRGYSPNETDDDGNYPLHIASKIN NNRIVAMLLTHGAKINNSVDEEGCCPLLACTDPSER VIERINLLVQYGAKINNSVDEEGCGPLLACTDPSER VFKKIMSIGFEARIVDKFGKNHIHRHLMSDNPICASTI SWMMKLGISPSKPDHDGNTPLHIVCSKTVKNVDIID    LLLPSTDVNKQNKFGDSPLTLLIKTLSPAHLINKLLS TSNVITDQTVNICIFYDRDDVLEIINDKGKQYDSTDF KMAVEVGSIRCVKYLLDNDIICEDAMYYAVLSEYE TMVDYLLFNHFSVDSVVNGHTCMSECVRLNNPVIL SKLMLHNPTSETMYLTMICAIEKDKLDKSIIIPFIAYF VLMHPDFCKNRRYFTSYICRFVTDYVHEGVSYEVFD DYF SEQ ID M2L AAA48004.1 MVYKLVLLFCIASLGYSVEYKNTICPPRQDYRYWY Inside NO:28 FAAELTIGVNYDINSTIIGECHMSESYIDRNANIVLTG Deletion YGLEINMTIMDTDQRFVAAAEGVGKDNICLSVLLFT TQRLDKVHHNISVTITCMEMNCGTTKYDSDLPESIH KSSSCDITINGSCVTCVNLETDPTIUNPHYLHPKDKY LYHNSEYGMRGSYGVTFIDELNQCLLDIICELSYDIC YRE SEQ ID HR/K1L AAA48005.1 MDLSRINTWKSKQLKSFLSSKDTFKADVHGHSALY Inside NO:29 YAIADNNVRLVCTLLNAGALKNLLENEFPLHQAAT Deletion LEDTKIVKILLFSGMDDSQFDDKGNTALYYAVDSG NMQTVKLFVKKNWRLMFYGKTGWKTSFYHAFML NDVSIVSYFLSEIPSTFDLAILLSCIHTTIKNGHVDMM ILLLDYMTSTNTNNSLLFIPDIKLAIDNICDIEMLQAL FKYDINIYSVNLENVLLDDAEITKMIIEKHVEYKSDS YTKDLDIVKNNICLDEIISKNKELRLMYVNCVKKN SEQ ID SPI- AAA48006.1 MIALLILSLTCSVSTYRLQGFTNAGIVAYKNIQDDNI Inside NO:30 3/K2L VFSPFGYSFSMFMSLLPASGNTRIELLKTMDLRKRD Deletion LGPAFTELISGLAKLKTSKYTYTDLTYQSFVDNTVCI KPLYYQQYHRFGLYRLNFRRDAVNIUNSIVERRSG MSNVVDSNMLDNNTLWAIINTIYFKGTWQYPFDIT KTRNASFTNKYGTKTVPMMNVVTKLQGNTITIDDE EYDMVRLPYKDANISMYLAIGDNMTHFIDSITAAK LDYWSFQLGNKVYNLICLPICFSIENKRDIKSIAEMM APSMFNPDNASFKHMTRDPLYIYICMFQNAKIDVDE QGTVAEASTIMVATARSSPEKLEFNTPFVFIIRHDITG FILFMGKVESP SEQ ID K ORF A AAA48007.1 MGHIITYCQVHTNISILIRKAHHIIFFVIDCDCISLQFS Inside NO:31 NYVHHGNRFRTVLISKTSIACFSDIKRILPCTFICIYSI Deletion NDCP SEQ ID K ORF B AAA48008.1 MGTVFVPYLLVICLALRVLVISNGYCHVPLKYIVLMI Inside NO:32 AHRVLLSSILESTTLDIPDLRSTIELILLTASRLICFNLY Deletion RPNL SEQ ID K ORF B AAA48009.1 MLAFCYSLPNAGDVIKGRVYEKDYALYIYLFDYPH Inside NO:33 SEAILAESVICMHMDRYVEYRDKLVGKTVKVKVIR Deletion VDYTKGYIDVNYICRMCRHQ SEQ ID K4L AAA48010.1 MNPDNTIAVITETIPIGMQFDKVYLSTFNMWREILSN  Inside NO:34 TTKTLDISSFYWSLSDEVGTNFGTIILNEIVQLPICRG Deletion VRVRVAVNKSNKPLKDVERLQMAGVEVRYIDITNI LGGVLHTKFWISDNTHIYLGSANMDWRSLTQVKEL GIAIFNNRNLAADLTQIFEVYWYLGVNNLPYNWKN FYPSYYNTDHPLSINVSGVPHSVFIASAPQQLCTME RTNDLTALLSCIRNASKFVYVSVMNFIPIIYSKAGKI LFWPYIEDELRRSAIDRQVSVKLLISCWQRSSFIMRN FLRSIAMLKSKNIDIEVKLFIVPDADPPIPYSRVNHAK YMVTDKTAYIGTSNWTGNYFTDTCGASINITPDDGL GLRQQLEDIFMRDWNSKYSYELYDTSPTKRCKLLK NMKQCTNDIYCDEIQPEKEIPEYSLE SEQ ID K5L AAA48011.1 MGATISILASYDNPNLFTAMILMSPLVNADAVSRLN Inside NO:35 LLAAKLMGTITPNAPVGKLCPESVSRDMDKVYKYQ Deletion YDPLINHEKIKAGFASQVLKATNKVRKIISKINTPRL SYSREQTMRLVMFQVHIISCNMQIVIE MSANCMFNLDNDYIYWKPITYPKALVFISHGAGKH SEQ ID K6L AAA48012.1 SGRYDELAENISSLGILVFSHDHIGHGRSNGEKMMI Inside NO:36 DDFGTARGNY Deletion SEQ ID K7R AAA48013.1 MATKLDYEDAVFYFVDDDKICSRDSIIDLIDEYITW Inside NO:37 LN RNHVIVFNKDITSCGRLYKELMKFDDVAIRYYGIDK Deletion INEIVEAMSEGDHYINFTKVHDQESLFATIGICAKITE HWGYKKISESRFQSLGNITDLMTDDNINILILFLEKK LN SEQ ID F1L AAA48014.1 MLSMFMCNNIVDYVDDIDNGIVQDIEDEASNNVDH Inside NO:38 DYVYPLPENMVYRFDKSTNILDYLSTERDHVMMA Deletion VRYYMSKQRLDDLYRQLPTKTRSYIDIINIYCDKVS NDYNRDMNIMYDMASTKSFTVYDINNEVNTILMD NKGLGVRLATISFITELGRRCMNPVKTIKMFTLLSHT ICDDCFVDYITDISPPDNTIPNTSTREYLKLIGITAIMF ATYKTLKYMIG SEQ ID DUT/F2 AAA48015.1 MFNMNINSPVRFVKETNRAKSPTRQSPGAAGYDLY Inside NO:39 L SAYDYTIPPGERQLIKTDISMSMPKICYGRIAPRSGLS Deletion LKGIDIGGGVIDEDYRGNIGVILINNGKCTFNVNTGD RIAQLIYQRIYYPELEEVQSLDSTNRGDQGFSTGLR SEQ ID F3L AAA48016.1 MPIFVNTVYCKNILALSMTKKFKTIIDAIGGNIIVNST Inside NO:40 (75% 3′) ILKKLSPYFRTHLRQKYTKNKDPVTRVCLDLDIHSL Deletion TSIVIYSYTGKVYIDSHNVVNLLRASILTSVEFITYTCI NFILRDFRICEYCVECYMMGIEYGLSNLLCHTKNFIA KHFLELEDDIIDNFDYLSMKLILESDELNVPDEDYV VDFVIKWYIKRRNKLGNLLLLIKNVIRSNYLSPRGIN NVKWILDCTKIFHCDKQPRKSYKYPFIEYPMNMDQI IDIFHMCTSTHVGEVVVYLIGGWMNNEIHNNAIAVN YISNNWIPIPPMNSPRLYATGIPANNKLYVVGGLPNP TSVERWFHGDAAWVNMPSLLKPRCNPAVASINNVI YVMGGHSETDTTTEYLLPNHDQWQFGPSTYYPHY KSCALVFGRRLFLVGRNAEFYCESSNTWTLIDDPIY RDNPELIIVDNICLLLIGGFYRGSYIDTIEVYNHHTY SWNIWDGK

TABLE 32 Examples of proteins encoded by Western Reserve Vaccinia genes equivalent  to those deleted in CopMD5p vector SEQ ID Protein NO. Gene Accession ID AA Sequence Location SEQ ID VACWR AA089305.1 MESVIFSINGEIIQVNKEIITASPYNFFKRIQDHHLKD Inside NO:41 026 EMILNGINYHAFESLLDYIRWICKINITINNVEMILVA Deletion (26% 5′) AIIIDVPPVVDLCVKTMIHNINSTNCIRMFNFSKRYGI KKLYNASMSEIINNITAVISDPEFGKLSKDELITTILS HENVNVNHEDVTAMILLKWIHKNPNDVDIINILHPK FMTNTMRNAISLLGLTISKSTKPVTRNGIKHNIVVIK NSDYISTITHYSPRTEYWTIVGNTDRQFYNANVLHN CLYIIGGMINNRHVYSVSRVDLETIUCWKTVTNMSS LKSEVSTCVNDGKLYVIGGLEFSISTGVAEYLKHGT SKWIRLPNLITPRYSGASVFVNDDIYVMGGVYTTYE KYVVLNDVECFTKNRWIKKSPMPRHHSIVYAVEYD GDIYVITGITHETRNYLYKYIVICEDKWIELYMYFNH VGKMFVCSCGDYILIIADAKYEYYPKSNTWNLFDM STRNIEYYDMFTKDETPKCNVTHKSLPSFLSNCEKQ FLQ SEQ ID VACWR AA089306.1 MVKNNKIQKNKISNSCRMIMSTDPNNILMRHLKNL Inside NO:42 027 TDDEFKCIIHRSSDFLYLSDSDYTSITKETLVSEIVEE Deletion YPDDCNKILAIIFLVLDKDIDVDIKTKLKPKPAVRFAI LDKMTEDIKLTDLVRHYFRYIEQDIPLGPLFKKIDSY RTRAINKYSICELGLATEYFNKYGHLMFYTLPIPYNR FFCRNSIGFLAVLSPTIGHVKAFYKFIEYVSIDDRRKF KKELMSK SEQ ID VACWR AA089307.1 MRTLLIRYILWRNDNDQTYYNDNFICKLMLLDELVD Inside NO:43 028 DGDVCTLIICNMRMTLSDGPLLDRLNQPVNNIEDAK Deletion RMIAISAKVARDIGERSEIRWEESFTILFRMIETYFDD LMIDLYGEK SEQ ID VACWR AA089308.1 MTSSAMDNNEPKVLEMVYDATILPEGSSMDPNIEMD Inside NO:44 029 CINRHINMCIQRTYSSSIIAILDRFLMMNICDELNNTQ Deletion CHIIICEFMTYEQMAIDHYGGYVNAILYQIRICRPNQH HTIDLFKRIKRTRYDTFKVDPVEFVICKVIGFVSILNK YKPVYSYVLYENVLYDEFKCFINYVETKYF SEQ ID VACWR AA089309.1 MIFVIESKLLQIYRNRNRNINFYTTNIDNIMSAEYYLS Inside NO:45 030 LYAKYNSKNLDVFRNMLQAIEPSGNNYHILHAYCG Deletion IKGLDERFVEELLHRGYSPNETDDDGNYPLHIASKIN NNRIVAMLLTHGADPNACDICHNKTPLYYLSGTDDE VIERINLLVQYGAKINNSVDEEGCGPLLACTDPSER VFKKIMSIGFEARIVDKFGKNHIHRHLMSDNPKASTI SWMMKLGISPSKPDHDGNTPLHIVCSKTVKNVDIID LLLPSTDVNKQNKFGDSPLTLLIKTLSPAHLINKLLS TSNVITDQTVNICIFYDRDDVLEIINDKGKQYDSTDF KMAVEVGSIRCVKYLLDNDIICEDAMYYAVLSEYE TMVDYLLFNHFSVDFVVNGHTCMSECVRLNNPVIL SKLMLHNPTSETMYLTMKAIEKDRLDKSIIIPFIAYF VLMHPDFCICNRRYFTSYKRFVTDYVHEGVSYEVFD DYF SEQ ID VACWR AA089310.1 MVYKLVLLFCIASLGYSVEYKNTICPPRQDYRYWY Inside NO:46 031 FAAELTIGVNYDINSTIIGECHMSESSYIDRNANIVLTG Deletion YGLEINMTIMDTDQRFVAAAEGVGICDNKLSVLLFT TQRLDKVHHNISVTITCMEMNCGTTKYDSDLPESIH KSSSCDITINGSCVTCVNLETDPTKINPHYLHPKDKY LYHNSEYSMRGSYGVTFIDELNQCLLDIKELSYDIC YRE SEQ ID VACWR AA089311.1 MDLSRINTWKSKQLKSFLSSKDAFKADVHGHSALY Inside No:47 032 YAIADNNVRLVCTLLNAGALICNLLENEFPLHQAAT Deletion LEDTKIVKILLFSGLDDSQFDDKGNTALYYAVDSGN MQTVKLFVICKNVVRLMFYGKTGWKTSFYHAVMLN DVSIVSYFLSEIPSTFDLAILLSCIHITIKNGHVDMMIL LLDYMTSTNTNNSLLFIPDIKLAIDNICDIEMLQALFK YDINIYSANLENVLLDDAEIAKMIIEKHVEYKSDSYT KDLDIVKNNKLDEIISICNKELRLMYVNCVKKN SEQ ID SPI-3 AA089312.1 MIALLILSLTCSVSTYRLQGFTNAGIVAYKNIQDDNI Inside NO:48 VFSPFGYSFSMFMSLLPASGNTRIELLKTMDLRKRD Deletion LGPAFTELISGLAKLKTSKYTYTDLTYQSFVDNTVCI KPSYYQQYHRFGLYRLNFRRDAVNKINSIVERRSG MSNVVDSNMLDNNTLWAIINTIYFKGIWQYPFDITK TRNASFTNKYGTKTVPMMNVVTKLQGNTITIDDEE YDMVRLPYICDANISMYLAIGDNMTHFTDSITAAKL DYWSFQLGNKVYNLKLPKFSIENKRDIKSIAEMMAP SMFNPDNASFKHMTRDPLYIYKMFQNAKIDVDEQG TVAEASTIMVATARSSPEICLEFNTPFVFIIRHDITGFI LFMGKVESP SEQ ID VACWR AA089313.1 MLAFCYSLPNAGDVIKGRVYEKDYALYIYLFDYPH Inside NO:49 34 FEAILAESVICMHMDRYVEYRDKLVGKTVKVKVIR Deletion VDYTKGYIDVNYKRMCRHQ SEQ ID VACWR AA089314.1 MNPDNTIAVITETIPIGMQFDKVYLSTFNMWREILSN Inside NO:50 035 TTKTLDISSFYWSLSDEVGTNFGTHLNKIVQLPICRG Deletion VRVRVAVNKSNKPLICDVERLQMAGVEVRYIDITNI LGGVLHTICFWISDNTHIYLGSANMDWRSLTQVKEL GIAIFNNRNLAADLTQIFEVYWYLGVNNLPYNWKN FYPSYYNTDHPLSINVSGVPHSVFIASAPQQLCTME RTNDLTALLSCIRNASKFVYVSVMNFIPHYSKAGNI LFWPYIEDELRRAAIDRQVSVKLLISCWQRSSFIMRN FLRSIAMLKSKNINIEVKLFIVPDADPPIPYSRVNHAK YMVTDKTAYIGTSNWTGNYFTDTCGASINITPDDGL GLRQQLEDIFMRDWNSKYSYELYDTSPTKRCRLLK NMKQCINDIYCDEIQPEICEIPEYSLE SEQ ID VACWR AA089315.1 MQHANCNREIKIYEGAKHHLHICETDEVICKSVMKEI Outside NO:51 036 ETWIFNRVK Deletion SEQ ID VACWR AA089316.1 MTLVQHVVTIKSTYWVIPWELASYDNPNLFTAMIL Inside NO:52 037 MSPLVNADAVSKLNLLAAKLMGTITLNAPVGKLCP Deletion ESVSRDMDKVYKYQYDPLINHEKHCAGFASQVLKA TNKVRKIISKINTPRLSYSREQTIRLAMF SEQ ID VACWR AA089317.1 MSANCMFNLDNDYIYWKPITYPKALVFISHGAGKH Inside NO:53 038 SGRYDELAENISSLGILVFSHDHIGHGRSNGEKMMI Deletion DDFGTARGNY SEQ ID VACWR MATKLDYEDAVFYFVDDDKICSRDSIIDLIDEYITW Inside NO:54 039 AA089318.1 RNHVIVFNKDITSCGRLYKELMKFDDVAIRYYGIDK Deletion INEIVEAMSEGDHYINFTKVHDQESLFATIGICAKITE HWGYKKISESRFQSLGNITDLMTDDNINILILFLEICK LN SEQ ID VACWR AA089319.1 MLSMFMCNNIVDYVDDIDNGIVQDIEDEASNNVDH Inside NO:55 040 DYVYPLPENMVYRFDKSTNILDYLSTERDHVMMA Deletion VRYYMSKQRLDDLYRQLPTKTRSYIDIINIYCDKVS NDYNRDMNIMYDMASTKSFTVYDINNEVNTILMD NICGLGVRLATISFITELGRRCMNPVETIKMFTLLSHT ICDDYFVDYITDISPPDNTIPNTSTREYLICIIGITAIMF ATYKTLKYMIG SEQ ID  DUT AA089320.1 MFNMNINSPVRFVKETNRAKSPTROQSPYAAGYDLY Inside NO:56 SAYDYTIPPGERQLIKTDISMSMPKFCYGRIAPRSGL Deletion SLKGIDIGGGVIDEDYRGNIGVILINNGKCTFNVNTG DRIAQLIYQRIYYPELEEVQSLDSTNRGDQGFGSTGL R SEQ ID VACWR MPIFVNTVYCKNILALSMTKICFKTIIDAIGGNIIVNST Inside NO:57 042 ILKKLSPYFRTHLRQKYTKNKDPVTWVCLDLDIHSL Deletion (75% 3′) TSIVIYSYTGKVYIDSHNVVNLLRASILTSVEFIIYTCI NFILRDFRKEYCVECYMMGIEYGLSNLLCHTICNFIA KHFLELEDDIIDNFDYLSMKLILESDELNVPDEDYV VDFVIKWYIICRRNICLGNLLLLIKNVIRSNYLSPRGIN NVKWILDCTKIFHCDKQPRKSYKYPFIEYPMNMDQI IDIFHMCTSTHVGEVVYLIGGWMNNEIHNNAIAVN YISNNWIPIPPMNSPRLYASGIPANNKLYVVGGLPNP TSVERWFHGDAAWVNMPSLLKPRCNPAVASINNVI YVMGGHSETDTTTEYLLPNHDQWQFGPSTYYPHY KSCALVFGFtRLFLVGRNAEFYCESSNTWTLIDDPIY PRDNPELIIVDNKLLLIGGFYRESYIDTIEVYNHHTYS WNIWDGK

TABLE 33 Examples of proteins encoded by Tian Tan Vaccinia genes  equivalent to those deleted in CopMD5p vector SEQ ID Protein NO Gene Accession ID AA Sequence Location SEQ ID TC2L MESVIFSINGEHQVNKEIITASPYNFFKRIQDHHLKD Inside NO:58 (26% 5′) AAF33878.I EAIILNGINYHAFESLLDYIRWKKTNITINNVEMILVA Deletion AIIIDVPPVVDLCVKTMIHNINSTNCIRMFNFSKQYGI KKLYNASMSEIINNITAVTSDPEFGKLSKDELTTILS HEDVNVNHEDVTAMILLKWIHKNPNDVDIINILHPK FMTNTMRNAISLLGLTISKSTKPVTRNGIKHNIVVIK NSDYISTITHYSPRTEYWTIVGNTDRQFYNANVLHN CLYIIGGMINNRHVYSVSRVDLETKKWKTVTNMSS LKSEVSTCVNNGKLYVIGGLEFSISTGVAEYLKHGT SKWIRLPNLITPRYSGASVFVNDDIYVMGGVYTTYE KYVVLNDVECFTKNRWIKKSPMPRHHSIVYAVEYD GDIYVITGITHETRNYLYKYIVKEDKWIELYMYFNH VGKMFVCSCGDYILIIADAKYEYYPKSNTWNLFDM STRNIEYYDMFTKDETPKCNVTHKSLPSFLSNCEKQ FLQ SEQ ID TC1L AAF33879.1 MVKNNKISNSCRMIMSTDPNNILMRHLKNLTDDEF Inside NO:59 KCIIHRSSDFLYLSDSDYTSITKETLVSEIVEEYPDDC Deletion NIULAIIFLVLDKDIDVDIKTKLKPKPAVRFAILDKM TEDIKLTDLVRHYFRYIEQDIPLGPLFKKIDSYRTRAI NKYSKELGLATEYFNKYGHLMFYTLPIPYNRFFCRN SIGFLAVLSPTIGHVKAFYKFIEYVSIDDRRKFKKEL MSK SEQ ID TNIL AAF33880.1 MRTLLIRYILWRNDNDQTYYNDDFKKLMLLDELVD Inside NO:60 DGDVCTLIKNMRMTLSDGPLLDRLNQPVNNIEDAK Deletion RMIAISAKVARDIGERSEIRWEESFTILFRMIETYFDD LMIDLYGEK SEQ ID TN2L AAF33881.1 MTSSAMDNNEPKVLEMVYDATILPEGSSMDPYIMD Inside NO:61 CINRHINMCIQRTYSSSIIAILDRFLMMNKDELNNTQ Deletion CHIIKNL SEQ ID TM1L AAF33882.1 MIFVIESKLLQIYRNRNRNINFYTTMDNIMSAEYYLS Inside N0:62 LYAKYNSKNLDVFRNMLQAIEPSGNNYHILHAYCG Deletion IKGLDERFVEELLHRGYSPNETDDDGNYPLHIASKIN NNRIVAMLLTHGADPNACDKHNKTPLYYLSGTDDE VIERINLLVQYGAKINNSVDEEGCGPLLACTDPSER VFKKIMSIGFEARIVDKFGKNHIHRHLMSDNPKASTI SWMMKLGISPSKPDHDGNTPLHIVCSKTVKNVDIID LLLPSTDVNKQNKFGDSPLTLLIKTLSPAHLINKLLS TSNVITDQTVNKIFYDRDDVLEIINDKGKQYDSTDF KMAVEVGSIRCVKYLLDNDIKEDAMYYAVLSEYE TMVDYLLFNHFSVDFVVNGHTCMSECVRLNNPVIL SKLMLHNLTSETMYLTMKAIEKDRLDKSIIIPFIAYF VLMHPDFCKNRRYFTSYKRFVTDYVHEGVSYEVFD DYF SEQ ID TM2L AAF33883.1 MSSSTRLPVLVLAAELTIGVNYDINSTIIGECHMSES Inside NO:63 YIDRNANIVLTGYGLEINMTIMDTDQRFVAAAEGV Deletion GKDNKLSVLLFTTQRLDKVHHNISVTITCMEMNCG TTKYDSDLPESIHKSSSCDITINGSCVTCVNLETDPT KINPHYLHPKDKYLYHNSEYGMRGSYGVTFIDELN QCLLDIKELSYDKYRE SEQ ID TK1L AAF33884.1 MLQALFKYDINIYSANLENVLLDDAEIAKMIIEKHV Inside NO:64 EYKSDSYTKDLDIVKNNKLDEIISKNKELRLMYVNC Deletion VKKN SEQ ID TK2L AAF33885.1 MDLSRINTWKSKQLKSFLSSKDTFKADVHGHSALY Inside NO:65 YAIADNNVRLVCTLLNSGALKNLLENEFPLHQAAT Deletion LEDTKIVKILLFSGLDDSQFDDKGNTALYYAVDSGN MQTVKLFVKKNVVRLMFYGKTGWKTSFYHAVMLN DVSIVSYFLSEIPSTFDLAILLSCIHITIKNGHVDMMIL LLDYMTVDKHQ SEQ ID TK3L AAF33886.1 MIALLILSLACSASAYRLQGFTNAGIVAYKNIQDDNI Inside NO:66 VFSPFGYSFSMFMSLLPASGNTRIELLKTMDLRKRD Deletion LGPAFTELISGLAKLKTSKYTYTDLTYQSFVDNTVCI KPSYYQQYHRFGLYRLNFRRDAVNKINSIVERRSG MSNVVDSNMLDNNTLWAIINTIYFKGTWQYPFDIT KTRNASFTNKYGTKTVPMMNVVTKLQGNTITIDDE EYDMVRLPYKDANISMYLAIGDNMTHFTDSITAAK DYWSFQLGNKVYNLKLPKFSIENKRDIKSIAEMMAP SMFNPDNASFKHMTRDPLYIYKMFQNAKIDVDEQG TVAEASTIMVATARSSPEELEFNTPFVFIIRHDITGFIL FMGKVESP SEQ ID ORFR AAF33887.1 MGHIITYCQVHTNISILIRKAYHIIFFVIDCDCISLQFS NO:67 NYVHHGNRFRTVLISKTSIACFSDIKRILPCTFKIYSI NDCP SEQ ID TK4L AAF33888.1 MLAFCYSLPNAGDVIKGRVYEKDYALYIYLFDYPH Inside NO:68 SEAILAESVKMHMDRYVEYRDKLVGKTVKVKVIR Deletion VDYTKGYIDVNYKRMCRHQ SEQ ID TK6L AAF33889.I MTLVQHVVTIKSTYWVIPWELASYDNPNLFTAMIL Inside N0:69 MSPLVNADAVSKLNLLAAKLMGTITLNAPVGKLCP Deletion ESVSRDMDKVYKYQYDPLINHEKIKAGFASQVLKA TNKVRKIISKINTPRLSYSREQTIRLAMF SEQ ID TK8R AAF33890.1  MATKLDYEDAVFYFVDDDKKSRDSIIDLIDEYITW Inside NO:70 RNHVIVFNKDITSCGRLYKELMKFDDVAIRYYGIDK Deletion INEIVEAMSEGDHYINFTKVHDQESLFATIGKAKITE HVVGYKKISESRFQSLGNITDLMTDDNINILILFLEKK LN SEQ ID TR1L AAF33891.1  MLSMFMCNNIVDYVDDIDNGIVQDIEDEASNNVDR Inside NO:71 DYVYPLPENMVYRFDKSTNILDYLSTERDHVMMA Deletion VRYYMSKQRLDDLYRQLPTKTRSYIDIINIYCDKVS NDYNRDMNIMYDMASTKSFTVYDINNEVNTILMD NKGLGVRLATISFITELGRRCMNPVKTIKMFTLLSHT KDDCFVDYITDISPPDNTIPNTSTREYLKLIGITAIMF ATYKTLKYMIG MFNMNINSPVRFVKETNRAKSPTRQSPGAAGYDLY Inside SEQ ID TF2L AAF33892.1  SAYDYTIPPGERQLIKTDISMSMPKKYGRIAPRSGLS Deletion N0:72 LKGIDIGGGVIDEDYRGNIGVILINNGKCTFNVNTGD RIAQLIYQRIYYPELEEVQSLDSTDRGDQGFGSTGLR SEQ ID TF3L AAF33903.1  MPIFVNTVYCKNILALSMTIUCFKTIIDAIGGNIIVNST Inside NO: 73 (75% 3′)  ILKKLSPYFRTHLRQKYTKNKDPVTRVCLDLDIHSL Deletion TSIVIYSYTGKVYIDSHNVVNLLRASILTSVEFHYTCI NFILRDFRKEYCVECYMMGIEYGLSNLLCHTKNFIA KHFLELEDDIIDNFDYLSMKLILESDELNVPDEDYV VDFVIKWYIKRRNKLGNLLLLIKNVIRSNYLSPRGIN NVKWILDCTKIFHCDKQPRKSYKYPFIEYPMNMDQI IDIFHMCTSTHVGEVVYLIGGWMNNEIHNNAIAVN YISNNWIPIPPMNSPRLYASGIPANNKLYVVGGLPNP TSVERWFHGDAAWVNMPSLLKPRCNPAVASINNVI YVMGGHSETDTTTEYLLPNHDQWQFGPSTYYPHY KSCALVFGRRLFLVGRNAEFYCESSNTWTLIDDPIY PRDNPELIIVDNKLLLIGGFYRESYIDTIEVYNHHTYS WNIWDGK TK5L ORFR TK7L

TABLE 34 Examples of proteins encoded by Wyeth Vaccinia genes  equivalent to those deleted in CopN1D5p vector Protein SEQ ID Accession  NO Gene ID Amino Acid Sequence Location SEQ ID VAC_D AEY74729.1 MESVIFSINGEHQVNKEHTASPYNFFKRIQEHHINDE Inside NO:74 PP20_03 VIILNGINYHAFESLLDYMRWKKINITINNVEMILVA Deletion 5 AVIIDVTPVVDLCVKTMIHNINSTNCIRMFNFSKRYG (26% 5′) IKKLYNASMSEIINNITAVTSDPEFGKLSKDELTTILS HEDVNVNHEDVTAMILLKWIHKNPNDVDIINILHPK FMTNTMRNAISLLGLTISKSTKPVTRNGIKHNIVVIK NSDYISTITHYSPRTEYWTIVGNTDRQFYNANVLHN LYIIGGMINNRHVYSVSRVDLETKKWKTVTNMSS LKSEVSTCVNNGKLYVIGGLEFSISTGVAEYLKHGT SKWIRLPNLITPRYSGASVFVNDDIYVMGGVYTTYE KYVVLNDVECFTKNRWIKKSPMPRHHSIVYAVEYD GDIYAITGITHETRNYLYKYIVKEDKWIELYMYFNH VGKMFVCSCGDYILIIADAKYEYYPKSNTWNLFDM STRNIEYYDMFTKDETHKSLPSFLSNCEKQFLQ SEQ ID VAC_D AEY74730.1 MVKNNKISNSCRMIMSTNPNNILMRFILKNLTDDEF Inside NO:75 PP10_03 KCIIHRSSDFLYLSDRDYTSITKETLVSEIVEEYPDDC Deletion 6 NKILAIIFLVLDKDIDVDIKTKLKPKPAVRFAILDKM TEDIKLTDLVRHYFRYIEQDIPLGPLFKKIDSYRTRAI NKYSKELGLATEYFNKYGHLMFYTLPIPYNFtFFCRN SIGFLAVLSPTIGHVKAFYKFIEYVSIDDRRKFIUCEL MSK SEQ ID NIL AEY74731A MRTLLIRYILWRNDNDQTYYNDDFKKLMLLDELVD Inside NO:76 DGDVCTLIKNMRMTLSDGPLLDRLNQPVNNIEDAK Deletion RMIAISAKVARDIGERSEIRWEESFTILFRMIETYFDD LMIDLYGEK SEQ ID VAC_D AEY74732.1 MTSSAMDNNEPKVLEMVYDATILPEGSSMDPNIIDC Inside NO:77 PP11_03 NRHINMCIQRTYSSSIIAILDRFLTMNKDELNNTQC Deletion 8 HIIKEFMTYEQMAIDHYGGYVNAILYQIRKRPNQHH TIDLFKKIKRTRYDTFKVDPVEFVKKVIGFVSILNKY KPVYSYVLYENVLYDEFKCFIDYVETKYF SEQ ID VAC_D AEY74733.1 MLHNPTSETMYLTMNAIKKDKLDKSIIIPFIAYFVLM Not NO:78 PP11_03 HPDFCKNRRYFTSYKRFVTDYVHEGVSYEVFDDYF Present 9 SEQ ID VAC_D AEY74734.1 MSIGFEARIVDKFGKNH1HRHLMSDNPKASTISWM Inside NO:79 PP12_04 MKLGISPSKPDHDGNTPLHIVCSKTVKYVDIIDLLLP Deletion 0  STDVNKQNFGDSPLTLLIKTLSLAHINKLLSTSNV ITDQTVNICIFYDRDDVLEIINDKGKQYDFKMAVEV GSIKCVKYLLDNDIKEDAMYYAVLSEYKTMVDYL LFNHFSVDSVVNGHTCMSECVKLNNRHFIEADVT SEQ ID VAC_D AEY74735.1 MIFVLESKLLQIYRNRNRNINFYTTMDNIMSAEYYLS Not NO:80 PP12_04 LYAKYNSKNLDVFRNMLQAIEPSGNNYHILHAYCG Present 1 IKGLDERFVEELLHRGYSPNETDDDGNYPLHIASKIN NNRIVAMLLTHGADPNACDKHNKTPLYYLSGTDDE VIERINLLVQYGAKINN SEQ ID VAC_D AEY74736.1 MVYKLVLLFCIASLGYSVEYKNTKPPRQDYRYWY Inside NO:81 PP12_04 FAAELTIGVNYDINSTIIGECHMSESYIDRNANIVLTG Deletion 2 YGLEINMTIMDTDQRFVAAAEGVGKDNKLSVLLFT TQRLDKVHHNISVTITCMEMNCGITKYDSDLPESIH KSSSCDITINGSCVTCVNLETDPTKINPHYLHPKDKY LYHNSEYGMRGSYGVTFIDELNQCLLDIKELSYDIC YRE SEQ ID VAC_D MDLSRINTWKSKQLKSFLSSKDTFKADVHGHSALY Inside NO:82 PP10_04 AEY74737.1 YAIADNNVRLVCTLLNAGALKNLLENEFPLHQAAT Deletion 3 LEDTKIVKILLFSGLDDSQFDDKGNTALYYAVDSGN MQTVKLFVKKNWRLMFYGKTGWKTSFYHAVMLN DVSIVSYFLSEIPSTFDLAILLSCIHITIKNGHVDMMIL LLDYMTSTNTNNSLLFIPDIKLAIDNKDIEMLQALFK YDINIYSANLENVLLDDAEIAKMIIEKHVEYKSDSYT KDLDIVKNNKLDEIISKNKELRLMYVNCVKKN SEQ ID VAC_D AEY74738.1 MIALLILSLTCSVSTYRLQGFTNAGIVAYKNIQDDNI Inside NO:83 PP20_04  VFSPFGYSFSMFMSLLPASGNTRIELLKTMDLRKRD Deletion 4 LGPAFTELISGLAKLKTSKYTYTDLTYQSFVDNTVCI KPSYYQQYHRLNFRRDAVNKINSIVERRSGMSNVV DSNMLDNNTLWAIINTIYFKGIWQYPFDITKTRNAS FTNKYGTKTVPMMNVVTKLQGNTITIDDKEYDMV RLPYKDANISMYLAIGDNMTHFTDSITAAKLDYWS FQLGNKVYNLKLPKFSIENKRDIKSIAEMMAPSMFN PDNASFKHMTRDPLYIYKMFQNAKIDVDEQGTVAE ASTIMVATARSSPEKLEFNTPFVFIIRHDITGFILFMG KVESP SEQ ID VAC_D AEY74739.1 MLAFCYSLPNAGDVIKGRVYENDYALYIYLFDYPH Inside NO:84 PP10_04 FEAILAESVKMHMDRYVEYRDKLVGKTVKVKVIR Deletion 5 VDYTKGYIDVNYKRMCRHQ SEQ ID K4L AEY74740.1 MNPDNTIAVITETIPIGMQFDKVYLSTFNMWREILSN Inside NO:85 TTKTLDISSFYWSLSDEVGTNFGTIILNEIVQLPKRG Deletion VRVRVAVNKSNKPLKDVERLQMAGVEVRYIDITNI LGGVLHTKFWISDNTHIYLGSANMDWRSLTQVKEL GIAIFNNRNLAADLTQIFEVYWYLGVNNLPYNWKN FYPSYYNTDHPLSINVSGVPHSVFIASAPQQLCTME RTNDLTALLSCIRNASKFVYVSVMNFIPHYSKAGKI LFWPYIEDELRRSAIDRQVSVKLLISCWQRSSFIMRN FLRSIAMLKSKNINIEVKLFIVPDADPPIPYSRVNHAK YMVTDKTAYIGTSNWTGNYFTDTCGASINITPDDGL GLRQQLEDIFMRDWNSKYSYELYDTSPTKRCKLLK NMKQCTNDIYCDEIQPEKEIPEYSLE SEQ ID VAC_D AEY74741.1 MGATISILASYDNPNLFTAMILMSPLVNADAVSKLN Inside NO:86 PP20_04  LLAAKLMGTITPNAPVGKLCPESVSRDMDKVYKYQ Deletion 7 YDPLINHEKIKAGFASQVLKATNKVRIUISKINTPPT LILQGTNNEISDVLGAYYFMQHANCNREIKIYEGAK HHLHKETDEVECKSVMKEIETWIFNRVK SEQ ID List034/ AEY74742.1 SANCMFNLDNDYIYWKPITYPKAINFISHGAGKH Inside NO:87  VAC_D SGRYDELAENISSLGILVFSHDHIGHGRSNGEKMMI Deletion PP20_04 DDFGTARGNY 8 SEQ ID K7R/VA AEY74743.1 MATKLDYEDAVFYFVDDDKKSRDSIIDLIDEYITW Inside NO:88 C_DPP2 RNHVIVFNKDITSCGRLYKELMKFDDVAIRYYGIDK Deletion 0-49 INEIVEAMSEGDHYINFTKVHDQESLFATIGKAKITE HWGYKKISESRFQSLGNITDLMTDDNINILILFLEKK LN SEQ ID LIVPclo AEY74744.1 MLSMFMCNNIVDYVDDIDNGIVQDIEDEASNNVDH Inside NO:89 ne14_04 DYVYPLPENMVYRFDKSTNILDYLSTERDHVMMA Deletion 6/VAC VRYYMSKQRLDDLYRQLPTKTRSYIDIINIYCDKVS DPP20_0 NDYNRDMNIMYDMASTKSFTVYDINNEVNTILMD 47 NKGLGVRLATISFITKLGRRCMNPVKTIKMFTLLSH TKDDCFVDYITDISPPDNTIPNTSTREYLKLIGITAIM FATYKTLKYMIG SEQ ID F2L/VA AEY74745.1 MFNMNINSPVREVKETNRAKSPTRQSPGAAGYDLY Inside NO:90 C_DPP2 SAYDYTIPPGERQLIKTDISMSMPKKYGRIAPRSGLS Deletion 0_051 LKGIDIGGGVIDEDYRGNIGVILINNGKCTFNVNTGD RIAQLIYQRIYYPELEEVQSLDSTNRGDQGFGSTGLR SEQ ID F3L AEY74746.1 MPIFVNTVYCKNILALSMTKKEKTIIDAIGGNIIVNST Inside NO:91  75% 3′) ILKKLSPYFRTHLRQKYTKNKDPVTRVCLDLDIHSL Deletion TSIVIYSYTGKVYIDSHNVVNLLRASILTSVEFIIYTCI NFILRDFRKEYCVECYMMGIEYGLSNLLCHTKNFIA KHFLELEDDIIDNFDYLSMKLILESDELNVPDEDYV VDFVIKWYEKRRNKLGNLLLLIKNVIRSNYLSPRGIN NVKWILDCTKIFHCDKQPRKSYKYPFIEYPMNMDQI IDIFHMCTSTHVGEVVYLIGGWMNNEIHNNAIAVN YISNNWIPIPPMNSPRLYASGIPANNKLYVVGGLPNP TSVERWFHGDAAWVNMPSLLKPRCNPAVASINNVI YVMGGHSETDTTTEYLLPNHDQWQFGPSTYYPHY KSCALVFGRRLFLVGRNAEFYCESSNTWTLIDDPIY PRDNPELIIVDNKILLIGGFYRESYIDTIEVYNHHTYS WNIWDGK

TABLE 35  Examples of proteins encoded by Lister Vaccinia genes equivalent to  those deleted in CopMD5pvector Protein SEQ ID Accession  NO Gene ID Amino Acid Sequence Location SEQ ID List023 ABD52473.1 MESVIFSINGEIIQVNKEIITASPYNFFKRIQDHHLKD Inside NO:92 (26% 5′) EAIILNGINYHAFESLLDYMRWKKINITINNVEMILV Deletion AAIIIDVPPVVDLCVKTMIHNINFTNCIRMFNFSKRY GIIKKLYNASMSEIINNITAVTSDPEFGKLSKDELTTIL SHEDVNVNHEDVTAMILLKWIHKNPNDVDIINILHP KFMTNTMRNAISLLGLTISKSTKPVTRNGIKHNIVVI KNSDYISTITHYSPRTEYWTIVGNTDRQFYNANVLH NCLYIIGGM1NNRHVYSVSRVDLKTKKWKTVTNMS SLKSEVSTCVNDGKLYVIGGLEFSISTGVAEYLKHG TSKWIRLPNLITPRYSGASVFVNDDIYVMGGVYTTY EKYVVLNDVECFTKNRWIKKSPMPRHHSIVYAVEY DGDIYVITGITHETRNYLYKYIVKEDKWIELYMYFN HVGKMFVCSCGDYILIIADAKYEYYPKSNTWNLFD MSTRNIEYYDMFT1CDETPKCNVTHKSLPSFLSNCEK QFLQ SEQ ID C1L/List ABD52474.1 MVKNNKISNSCRMIMSTNPNNILMRHLKNLTDDEF Inside NO:93 024 KCIIHRSSDFLYLSDSDYTSITKETLVSEIVEEYPDDC Deletion NKILAIIFLVLDKDIDVDIETKLKPKPAVRFAILDKM TADIKLTDLVRHYFRYIEQDIPLGPLFKKIDSYRTRAI NKYSKELGLATEYFNKYGHLMFYTLPIPYNRFFCRN SIGFLAVLSPTIGHVKAFYKFIEYVSIDDRRKFKKEL MSK SEQ ID NIL/List  ABD52475.1 MRTLLIRYILWRNDNDQTYYNDDFKKLMLLDELVD Inside NO:94 025 DGDVCTLIKNMRMTLSDGPLLDRLNQPVNNIEDAK Deletion RMIAISAKVARDIGERSEIRWEESFTILFRMIETYFDD LMIDLYGEK SEQ ID List026 ABD52476.1 MTSSAMDNNEPKVLEMVYDATILPEGSSMDPNIMD Inside NO:95 CINRHINMCIQRTYSSSIIAILDRFLTMNKDELNNTQ Deletion CHIIKEFMTYEQMAIDHYGEYVNAILYQIRKRPNQH HTIDLFKKIKRTRYDTEKVDPVEFVKKVIGFVSILNK YKPVYSYVLYENVLYDEFKCFIDYVETKYF SEQ ID List027 ABD52477.1 MIFVIESKLLQIYRNRNINFYTTMDNIMSAEYYLSLY Inside N0:96 AKYNSKNLDVFRNMLQAMPSGNNYHILHAYCGIK Deletion GLDERFVEELLHRGYSPNETDDDGNYPLHIASKINN NRIVAMLLTHGADPNACDKQHKTPLYYLSGTDDEV IERINLLVQYGAKINNSVDEEGCGPLLACTDPSERVF KKIMSIGFEARIVDKFGKNHIHRHLMSDNPKASTIS WMMKLGISPSKPDHDGNTPLHIVCSKTVKNVDIIDL LLPSTDVNKQNKFGDSPLTLLIKTLSPAHLINKLLST SNVITDQTVNKIFYDRDDVLEIINDKGKQYDSTDFK MAVEVGSIRCVKYLLDNDIKEDAMYYAVLSEYET MVDYLLFNHFSVDSVVNGHTCMSECVRLNNPVILS KLMLHNPTSETMYLTMKAIEKDRLDKSIIIPFIAYFV LMHPDFCKNRRYFTSYKRFVTDYVHEGVSYEVFDD YF SEQ ID List028 ABD52478.1 MVYKLVLLFCIASLGYSVEYKNTKPPRQDYRYWY Inside NO:97 FAAELTIGVNYDINSTIIGECHMSESYIDRNANIVLTG Deletion YGLEINMTIMDTDQRFVAAAEGVGKDNKLSVLLFT TQRLDKVHHNISVTITCMEMNCGTTKYDSDLPESIH KSSSCDITINGSCVTCVNLETDPTKINPHYLHPKDKY LYHNSEYGMRGSYGVTFIDELNQCLLDIKELSYDK YRE SEQ OD K1L/List029 ABD52479.1 MDLSRINTWKSKQLKSFLSSKDAFKADINGHSALY Inside NO:98 029 YAIADNNVRLVCTLLNAGALKNLLENEFPLHQAAT Deletion LEDTKIVKILLFSGLDDSQFDDKGNTALYYAVDSGN MQTVKLFVKKNWRLMFYGKTGWKTSFYHAVMLN DVSIVSYFLSEIPSTFDLAILLSCIHITIKNGHVDMMIL LLDYMTSTNTNNSLLFIPDIKLAIDNKDIEMLQALFK YDINIYSANLENVLLDDAEIAKMIIEKHVEYKSDSYT KDLDIVKNNKLDEIISKNKELKLMYVNCVKKN SEQ ID List030 ABD52480.1 IELLKTMDLRKRDLGPAFTELISGLAKLKTSKYTYT Inside NO:99 DLTYQSFVDNTVCIKPSYYQQYHRFGLYRLNFRRD Deletion AVNKINSIVERRSGMSNVVDSNMLDNNTLWAIINTI YFKGIWQYPFDITKTRNASFTNKYGTKTVPMMN  TKLQGNTITIDDEEYDMVRLPYKDANISMYLAIGDN MTHFTDSITAAKLDYWSSQLGNKVYNLKLPKFSIEN KRDIKSIAEMMAPSMFNPDNASFKHMTRDPLYIYK MFQNAKIDVDEQGTVAEASTIMVATARSSPEKLEFN TPFVFIIRHDITGFILFMGKVESP SEQ ID K3L/List ABD52483.1 MLAFCYSLPNAGDVIKGRVYENDYALYIYLFDYPH Inside NO:100 031 SEAILAESVKMHMDRYVEYRDKLVGKTVKVKVIR Deletion VDYTKGYIDVNYKRMCRHQ SEQ ID K4L/List ABD52484.1 MNPDNTIAVITETIPIGMQFDKVYLSTFNMWREILSN Inside N0:101 032 TTKTLDISSFYWSLSDEVGTNFGTIILNEIVQLPKRG Deletion VRVRVAVNKSNKPLKDVERLQMAGVEVRYIDITNI LGGVLHTKFWISDNTHIYLGSANMDWRSLTQVKEL GIAIFNNRNLAADLTQIFEVYWYLGVNNLPYNWKN FYPSYYNTDHPLSINVSGVPHSVFIASAPQQLCTME RTNDLTALLSCIRNASKEVYVSVMNFIPHYSKAGKI LFWPYIEDELRRSAIDRQVSVKLLISCWQRSSFIMRN FLRSIAMLKSKNINIEVKLFIVPDADPPIPYSRVNHAK YMVTDKTAYIGTSNWTGNYFTDTCGASINITPDDGL GLRQQLEDIFMRDWNSKYSYELYDTSPTKRCKLLK NMKQCTNDIYCDEIQPEKEIPEYSLE SEQ ID List033 ABD52485.1 MGHSMGATISILASYDNPNLFTAMILMSPLVNADA Outside NO:102 VSRLNLLAAKLMGTITPNAPVGKLCPESVSRDMDK Deletion VYKYQYDPLINHEKIKAGFASQVLKATNKVRKIISKI NTPPTLILQGTNNIUSDVLGAYYFMQHANCNREIKI YEGAKHHLHKETDEVKKSVMKEIETWIFNRVK SEQ ID List034 ABD52486.1 MSANCMFNLDNDYIYWKPITYPKALVFISHGAGKH Inside NO:103 SGRYDELAENISSLGILVFSHDHIGHGRSNGEKMMI Deletion DDFGTARGNY SEQ ID K7R/List ABD52487.1 MATKLDYEDAVFYFVDDDKKSRDSIIDLIDEYITW Inside NO:104 035 RNHVIVFNKDITSCGRLYKELMKFDDVAIRYYGIDK Deletion INEIVEAMSEGDHYINFTKVHDQESLFATIGKAKITE HWGYKIUSESRFQSLGNITDLMTDDNINILILFLEKK LN SEQ ID F1L/List ABD52489.1 MLSMFMCNNIVDYVDDIDNGIVQDIEDEASNNVDH Inside NO:105 036 DYVYPLPENMVYRFDKSTNILDYLSTERDHVMMA Deletion VRYYMSKQRLDDLYRQLPTKTRSYIDIINIYCDKVS NDYNRDMNIMYDMASTKSFTVYDINNEVNTILMD NKGLGVRLATISFITELGRRCMNPVKTIKMFTLLSHT KDDCFVDYITDISPPDNTIPNTSTREYLKLIGITAIMF ATYKTLKYMIG SEQ ID List037 ABD52490.1 MFNMNINSPVRFVKETNRAKSPTRQSPGAAGYDLY Inside NO:106 SAYDYTIPPGERQLIKTDISMSMPKFCYGRIAPRSGL Deletion SLKGIDIGGGV1DEDYRGNIGVILINNGKCTFNVNTG DRIAQLIYQRIYYPELEEVQSLDSTNRGDQGFGSTGL R SEQ ID List038 ABD52491.1 MPIFVNTVYCKNILALSMTKKFKTIIDAIGGNIIVNST Inside NO:107 75% 3′) ILKKLSPYFRTHLRQKYTKNKDPVTRVCLDLDIHSL Deletion TSIVIYSTGKVYIDSHNVVNLLRASILTSVEFIIYTCI NFILRDFRKEYCVECYMMGIEYGLSNLLCHTKNFIA KHFLELEDDIIDNFDYLSIKLILESDELNVPDEDYVV DFVIKWYIKRRNKLGNLLLLIKNVIRSNYLSPRGINN VKWILDCTKIFHCDKQPRKSYKYPFIEYPMNMDQII DIFHMCTSTHVGEVVYLIGGWMNNEIHNNAIAVNY ISNNWIPIPPMNSPRLYASGIPANNKLYVVGGLPNPT SVERWFHGDAAWVNMPSLLKPRCNPAVASINNVIY VMGGHSETDTTTEYLLPNHDQWQFGPSTYYPHYKS CALVFGRRLFLVGRNAEFYCESSNTWTLIDDPIYPR DNPELIIVDNKLLLIGGFYRESYIDTIEVYNIIHTYSW NIWDGK

TABLE 36  Examples of proteins encoded by Copenhagen Vaccinia genes deleted in CopMD3p vector SEQ ID Protein NO Gene Accession ID Amino Acid Sequence Location SEQ ID B14R AAA49211.1 MNHCLLAISAVYFKAKWLTPFEKEFTSDYPFYVSPT Inside NO:108 (41% 3′)  EMVDVSMMSMYGELFNHASVKESFGNFSHELPYV Deletion GDTSMMVILPDKIDGLESIEQNLTDTNFKKWCNSLD AMFIDVHIPKFKVTGSYNLVDTLVKSGLTEVFGSTG DYSNMCNLDVSVDAMIHKTYIDVNEEYTEAAAATC ALVSDCASTITNEFCVDHPFIYVIRHVDGKILFVGRY CSPTTNC SEQ ID B15R AAA49212.1 MTANFSTHVFSPQHCGCDRLTSIDDVKQCLTEYIYVV Inside NO:109 SSYAYRNRQCAGQLYSTLLSFRDDAELVFIDIRELV Deletion KNMPWDDVKDCTEIIRCYIPDEQKTIREISAIIGLCA YAATYWGGEDHPTSNSLNALFVMLEMLNYVDYNII FRRMN SEQ ID B ORF E AAA48213.1 MYNSSIHTPEYDVIIHVIEHLKHHKQCVQTVTSGMV Inside NO:110 FTSPVSSSKTKSDDGRNLSDGFLLIRYITTDDFCTIF Deletion DIIPRHIFYQLANVDEH SEQ ID B16R AAA48214.1 MSILPVIFLPIFFYSSFVQTFNASECIDKGXYFASFME Inside NO:111 LENEPVILPCPQINTLSSGYNILDILWEKRGADNDRII Deletion PIDNGSNMLILNPTQSDSGIYKITTNETYCDMMSLN LTIVSVSESNIDFISYPQIVNERSTGEMVCPNINAFIAS NVNADIIWSGHRRLRNKRLKQRTPGIITIEDVRKND AGYYTCVLEYIYGGKTYNVTRIVKLEVRDKIIHPTM QLPEGVVTSIGSNLTIACRVSLRPPTTDADVFWISNG MYYEEDDGDGDGRISVANKIYMTDKRRVITSRLNI NPVKEEDATTFTCMAFTIPSISKTVTVSIT SEQ ID B ORF F AAA48215.1 MVIIPGVRCLSLLFLRRRCPLHIISAFTLLAINALILGH Inside NO:112 TISPVDLSFTKGYEIKSIFDSETDTIVKFNDIMSQ Deletion SEQ ID B17L AAA48216.1 MSRKFMQVYEYDREQYLDEFIEDRYNDSFITSPEYY Inside NO:113 SAEKYMCRYTTLNHNCVNVRRCALDSKLLHDIITN Deletion CKIYNNIELVRATKFVYYLDLIKCNWVSKVGDSVL YPVIFITHTSTRNLDKVSVKTYKGVKVKKLNRCAD HAIVINPFVKFKLTLPNKTSHAKVLVTFCKLRTDITP VEAPLPGNVLVYTFPDINKRIPGYIHVNIEGCIDGMI YINSSKFACVLKLHRSMYRIPPFPIDKSCCSQYTND DIEIPIHDLIKDVAIFKNKETVYYLKLNNKTIARFTYF NNIDTAITQEHEYVKIALGIVCKLMINNMHSIVGVN HSNTFVNCLLEDNV SEQ ID B18R AAA48217.1 MSRRLIYVLNINRKSTHKIQENEIYTYFSHCNIDHTS Inside NO:114 TELDFVVKNYDLNRRQHVTGYTALHCYLYNNYFT Deletion NDVLKILLNHDVNVTMKTSSGRMPVYILLTRCCNIS HDVVIDMIDKDKNHLSHRDYSNLLLEYIKSRYMLL KEEDIDENIVSTLLDKGIDPNFKQDGYTALHYYYLC LAHVYKPGECRKPITIKKAKRIISLFIQHGANLNALD NCGNTPFHLYLSIEMCNNIHMTKMLLTFNPNFKKN NHGLTPILCYITSDYIQHDILVMLIHHYETNVGEMPI DERRMIVFEFIKTYSTRPADSITYLMNRFKNINIYTR YEGKTLLHVACEYNNTQVIDYLIRINGDINALTDNN KHATQLIIDNKENSPYTINCLLYILRYIVDKNVIRSLV DQLPSLPIFDIKSFEKFISYCILLDDTFYDRHVKNRDS KTYRYAFSKYMSFDKYDGIITKCHDETMLLKLSTVL DTTLYAVLRCHNSRKLRRYLTELKKYNNDKSFKIY SNIMNERYLNVYYKDMYVSKVYDKLFPVFTDKNC LLTLLPSEIIYEILYMLTINDLYNISYPPTKV SEQ ID B19R AAA48218.1 MTMKMMVHIYFVSLSLLLLLFHSYAIDIENEITEFFN Inside NO:115 KMRDTLPAKDSKWLNPACMFGGTMNDMATLGEPF Deletion SAKCPPIEDSLLSHRYKDYVVKWERLEKNRRRQVS NKRVKHGDLWIANYTSKFSNRRYLCTVTTKNGDC VQGIVRSHIKKPPSCIPKTYELGTHDKYGIDLYCGIL YAKHYNNITWYKDNKEINIDDIKYSQTGKELIIHNPE LEDSGRYDCYVHYDDVRIKNDIVVSRCKILTVIPSQ DHRFKLILDPKINVTIGEPANITCTAVSTSLLIDDVLI EWENPSGWLIGFDFDVYSVLTSRGGITEATLYFENV TEEYIGNTYKCRGHNYYFEKTLITTVVLE SEQ ID B20R AAA48219.1 MDEDTRLSRYLYLTDREHINVDSIKQLCKISDPNAC Inside NO:116:  YRCGCTALHEYFYNYRSVNGKYKYRYNGYYQYYS Deletion SSDYENYNEYYYDDYDRTGMNSESDSESDNISIKTE YENEYEFYDETQDQSTQHNDL SEQ ID B21R AAA48220.1 MSLESFIITTFNNNSSTNIDNMCHLYVKVCPSSLLFR Inside NO:117 LFVECCDINKLVEGTTPLHCYLMNEGFESSVLKNLL Deletion KEYVMNTFNVHDIHYTNI SEQ ID B22R AAA48221.1 MISLSFLIHNPLKKWKLKPSISINGYRSTFTMAFPCA Inside NO:118 QFRPCHCHATKDSLNTVADVRHCLTEYILWVSHRW Deletion THRESAGSLYRLLISFRTDATELFGGELKDSLPWDNI DNCVEIIKCFIRNDSMKTAEELRAIIGLCTQSAIVSGR VFNDKYIDILLMLRKILNENDYLTLLDHIRTAKY SEQ ID B23R AAA48222.1 MIAFIIFREIGIISTRIAMDYCGRECTILCRLLDEDVTY Inside NO:119 KKIKLEIETCHNLSKHIDRRGNNALHCYVSNKCDTD Deletion IKIVRLLLSRGVERLCRNNEGLTPLGAYSKHRYVKS QIVHLLISSYSNSSNELKSNINDFDLSSDNIDLRLLKY LIVDKRIRPSKNTNYAINGLGLVDIYVTTPNPRPEVL LWLLKSECYSTGYVFRTCMYNSDMCKNSLHYYISS HRESQSLSKDVIKCLINNNVSIHGRDEGGSLPIQYY WSFSTIDIEIVKLLLIKDVDTCRVYDVSPILEAYYLN KRFRVTPYNVDMEIVNLLIERRHTLVDVMRSITSYD SREYNHYIIDNILKRFRQQDESIVQAMLINYLHYGD MVVRCMLDNGQQLSSARLLC SEQ ID B24R AAA48223.1 MYGLILSRFNNCGYHCYETILIDVFDILSKYMDDID Inside NO:120 MIDNENKTLLYYAVDVNNIQFAKRLLEYGASVTTS Deletion RSIINTAIQKSSYQRENKTRIVDLLLSYHPTLETMIDA FNRDIRYLYPEPLFACIRYALILDDDFPSKVSMISPVII RN SEQ ID B ORF G AAA48224.1 MRRCIHIKERKIHMTNIVDRNVTFILTVVHKYVRYV Inside NO:121  PHTVANDAHNLVHLAHLIHFIIYFFIIRDVRKKKKKK Deletion KKNRTIYFFSNVYARHIK SEQ ID B25R AAA48225.1 MSRINITKKIYCSVFLFLFLFLSYISNYEKVNDEMYE Inside NO:122 MGEMDEIVSIVRDSM1ArYIPNVFMDDGKNEGHVSV Deletion NNVCIIMYFTFFDVDTSSHLFKLVIKHCDLNKRGNS PLHCYTMNTRFNPSVLKILLHHGMRNFDSKDEKGH HYLIHSLSIDNKIFDILTDTIDDFSKSSDLLLCYLRYK FNGSLNYYVLYKGSDPNCADEDELTSLHYYCKHIST FYKSNYYKLSHTKMRAEKRFIYAIIDYGANINAVTH LPSTVYQT SEQ ID B26R AAA48226.1 MEQTLTRLHTYLQQYTKHSPRVVYALLSRGYVHLI Inside NO:123 VHPSWNDCATGHILIMLLNWHEQKEEGQHLLYLFI Deletion KHNQGYTLNILRYLLDRFDIQKDEYIYRLSKL SEQ ID B27R AAA48227.1 MLPHTSDTTSTFRLKTVFDLVFENRNIIYKADVVNDI Inside NO:124 IHHRLKVSLPMIKSLFYKMSEFSPYDDYYVKKILAY Deletion CLLRDESFAELHSKFCLNEDYKSVFMKNISFDKIDSII VT SEQ ID B28R AAA48228.I MKSVLYSYILFLSCIIINGRDIAPHAPSDGKCI(DNEY Inside NO:125 KRHNLCPGTYASRLCDSKTNTQCTPCGSGTFTSRNN Deletion HLPACLSCNGRRDRVTLLTIESVNALPDIIVFSKDHP DARHVFPKQNVE SEQ ID C23L/B2 AAA48229.1 MHVPASLQQSSSSSSSCTEEENKHHMGIDVIIKVTK Inside NO:126 9R (44% QDQTPTNDKKQSVTEITESESDPDPEVESEDDSTSV Deletion 5,) EDVDPPTTYYSIIGGGLRMNFGFTKCPQIKSISESAD GNTVNARLSSVSPGQGKDSPAITREEALAMIKDCEV SIDIRCSEEEKDSDIKTHPVLGSNISHKKVSYEDIIGST IVDTKCVKNLEFSVRIGDMCKESSELEVKDGFKYVD GSASEGATDDTSLIDSTKLKACV

TABLE 37 Examples of proteins encoded by Western Reserve Vaccinia genes  equivalent to those deleted in CopMD3p vector Protein SEQ ID Accession  NO Gene ID Amino Acid Sequence Location SEQ ID SPI- AO89474.1 MDIFREIASSMKGENVFISPASISSVLTILYYGANGST Inside NO:127 VACWR AEQLSKYVEKEENMDKVSAQNISFKSINKVYGRYS Deletion 195 AVFKDSFLRKIGDKFQTVDFTDCRTIDAINKCVDIFT (26% 3′)  EGKINPLLDEPLSPDTCLLAISAVYFKAKWLTPFEKE FTSDYPFYVSPTEMVDVSMMSMYGKAFNHASVKE SFGNFSIIELPYVGDTSMMVILPDKIDGLESIEQNLTD TNFKKWCNSLEATFIDVHIPKFKVTGSYNLVDTLVK SGLTEVFGSTGDYSNMCNSDVSVDAMIHKTYIDVN EEYTEAAAATCALVSDCASTITNEFCVDHPFIYVIRH VDGKILFVGRYCSPTTNC SEQ ID VACWR AAO89475.1 MTANFSTHVFSPQHCGCDRLTSIDDVRQCLTEYIYW Inside NO:128 196 SSYAYRNRQCAGQLYSTLLSFRDDAELVFIDIRELV Deletion KNMPWDDVKDCAEIIRCYIPDEQKTIREISAIIGLCA YAATYWGGEDHPTSNSLNALFVMLEMLNYVDYNII FRRMN SEQ ID VACWR AAO89476.1 MSILPVIFLSIFFYSSFVQTFNAPECIDKGQYFASFME Inside NO:129 197 LENEPVILPCPQINTLSSGYNILDILWEKRGADNDRII Deletion PIDNGSNMLILNPTQSDSGIYKITTNETYCDMMSLN LTIVSVSESNIDLISYPQIVNERSTGEMVCPNINAFIAS NVNADIIWSGHRRLRNKRLKQRTPGIITIEDVRKND AGYYTCVLEYIYGGKTYNVTRIVKLEVRDKIIPSTM QLPDGIVTSIGSNLTIACRVSLRPPTTDADVFWISNG MYYEEDDGDGNGRISVANKIYMTDKRRVITSRLNI NPVKEEDATTFTCMAFTIPSISKTVTVSIT SEQ ID VACWR AAO89477.1 MSRKFMQVYEYDREQYLDEFIEDRYNDSFITSPEYY Inside NO:130 198 SAEKYMCRYTTLNHNCINVRRCALDSKLLHDIITNC Deletion KIYNNIELVRATKFVYYLDLIKCNWVSKVGDSVLYP VIFITHTSTRNLDKVSVKTYKGVKVKKLNRCADHAI VINPFVKFKLTLPNKTSHAKVLVTFCKLKTDITPVEA PLPGNVLVYTFPDINKRIPGYIHLNIEGCIDGMIYINS SKFACVLKLHRSMYRIPPFPIDKSCCSQYINYDIEIPI HDLIKDVAIFKNKETVYYLKLNNKTIARFTYFNNID TAITQEHEYVIUALGIVCKLMINNMHSIVGVNHSNT FVNCLLEDNV SEQ ID VACWR AAO89478.1 MSRRLIYVLNINRESTHKIQENEIYTYFSHCNIDHTST Inside NO:131 199 ELDFVVKNYDLNRRQPVTGYTALHCYLYNNYFTN Deletion DVLKILLNHGVDVTMKTSSGRMPVYILLTRCCNISH DVVIDMIDKDKNHLLHRDYSNLLLEYIKSRYMLLK EEDIDENIVSTLLDKGIDPNFKQDGYTALHYYYLCL AHVYKPGECRKPITIKKAKRIISLFIQHGANLNALDN CGNTPFHLYLSIEMCNNIHMTKMLLTFNPNFEKNN HGLTPILCYITSDYIQHDILVMLIHHYETNVGEMPID ERRIIVFEFIKTYSTRPADSITYLMNRFKNIDIYTRYE GKTLLHVACEYNNTHVIDYLIRINGDINALTDNNKH ATQLIIDNKENSPYTINCLLYILRYIVDKNVIRSLVDQ LPSLPIFDIKSFEKFISYCILLDDTFYNRHVRNRDSKT YRYAFSKYMSFDKYDGIITKCHKETILLKLSTVLDT TLYAVLRCHNSKURRYLTELKKYNNDKSFKIYSNI MNERYLNVYYKDMYVSKVYDKLFPVFTDKNCLLT LLPSEIIYEILYMLTINDLYNISYPPTKV SEQ ID B18R/V AAO89479.1 MTMKMMVHIYFVSLLLLLFHSYAIDIENEITEFFNK Inside NO:132 ACWR2 MRDTLPAKDSKWLNPACMFGGTMNDIAALGEPFS Deletion 00 AKCPPIEDSLLSHRYKDYVVKWERLEKNRRRQVSN KRVKHGDLWIANYTSKFSNRRYLCTVTTKNGDCV QGIVSHIRKPPSCIPKTYELGTHDKYGIDLYCGILY AKHYNNITWYKDNKEINIDDIKYSQTGKELIIHNPEL EDSGRYDCYVHYDDVRIKNDIVVSRCIULTVIPSQD HRFKLILDPKINVTIGEPANITCTAVSTSLLIDDVLIE WENPSGWLIGFDFDVYSVLTSRGGITEATLYFENVT EEYIGNTYKCRGHNYYFEKTLTTTVVLE SEQ ID VACWR AAO89480.1 MHVIDVDVRLYMSTFIIIDQSTENTSIDTTVTINIIYL Not NO:133 201 AIMKIIMNIIMMIMIELV Present SEQ ID VACWR AAO89481.1 MNSESDNISIKTEYEFYDETQDQSTQLVGYDIKLKT Not NO:134 202 NEDDFMANIDQWVSMII Present SEQ ID VACWR AAO89482.1 MEMYPRHRYSKHSVFKGFSDKVRKNDLDMNVVKE Inside NO:135 203 LLSNGASLTIKDSSNKDPITVYFRRTIMNLEMIDERK Deletion YIVHSYLKNYKNFDYPFFRKLVLTNKHCLNNYYNIS DSKYGTPLHILASNKKLITPNYMKLLVYNGNDINAR GEDTQMRTPLHKYLCKFVYHNIEYGIRYYNEKIIDA FIELGADLTIPNDDGMIPVVYCIHSNAEYGYNNITNI KIIRKLLNLSRRASHNLFRDRVMHDYISNTYIDLECL DIIRSLDGFDINGYFEGRTPLHCAIQHNFTQIAKYLL DRGADIVVPNTLIIHQYIQ SEQ ID VACWR AAO89483.1 MLNFSLCLYPVFILNKLVLRTQSIILHTINNASIKNR Not NOS 677 204 \\\\\\ and \\\\\\ Present and 136 MEEDTNISNKVIRYNTVNNIWETLPNFWTGTINPGV VSHKDDIYVVCDIKDEKNVKTCIFRYNTNTYNGWE LVTTTESRLSALHTILYNNTIMMLHCYESYMLQDTF NVYTREWNHMCHQHSNSYIMYNILPIY SEQ ID 1/VACW SPI-  MDIFKELILKHTDENVLISPVSILSTLSILNHGAAGST Outside NO:137 AAO89484.1 AEQLSKYIENIVINENTPDDNNDMDVDIPYCATLATA Deletion NKIYGSDSIEFHASFLQKIKDDFQTVNFNNANQTKE LINEWVKTMTNGKINSLLTSPLSINTRMTVVSAVHF KAMWKYPFSKHLTYTDKFYISKNIVTSVDMMVSTE NNLQYVHINELFGGFSIIDIPYEGNSSMVIILPDDIEGI YNIEKNITDEKFKKWCGMLSTKSIDLYMPKFKVEM TEPYNLVPILENLGLTNIFGYYADFSKMCNETITVEK FLHTTFIDVNEEYTEASAVTGVFMTNFSMVYRTKV YINHPFMYMIKDNTGRILFIGKYCYPQ SEQ ID Cl3L/V AAO89485.1 MMIYGLIACLIFVTSSIASPLYIPVIPPISEDKSFNSVE Outside NO:138 ACWR2 VLVSLFRDDQKDYTVTSQFNNYTIDTKDWTIGVLST Deletion 06 PDGLDIPLTNITYWSRFTIGRALFKSESEDIFQKKMSI LGVSIECKKSSTLLTFLTVRKMTRVFNKFPDMAYYR GDCLKAVYVTMTYKNTKTGETDYTYLSNGGLPAY YRNGVDG SEQ ID VACWR AAO89486.1 MKLFTQNDRYFGLLDSCTHIFCITCINIWHKTRRETG Outside NO:139 207 ASDNCPKRTRFRNITMSKFYKLVN Deletion SEQ ID p28/VA AA089487.1 MEFDPAKINTSSIDHVTILQYIDEPNDIRLTVCIIRNIN Outside NO:140 CWR208 NITYYINITKINTHLANQFRAWKKRIAGRDYMTNLS Deletion RDTGIQQSKLTETIRNCQKNRNIYGLYIHYNLVINVV IDWITDVIVQSILRGLVNWYIANNTYTPNTPNNTTTI SELDIIKILDKVEDVYRVSKEKECGKYEVVYSKR SEQ ID C10L/V AAO89488.1 MDIYDDKGLQTIKLFNNEFDCIRNDIRELFKHVTDS Outside NO:141 ACWR2 DSIQLPMEDNSDIIENIRKILYRRLKNVECVDIDSTIT Deletion 09 FMKYDPNDDNKRTCSNWVPLTNNYMEYCLVIYLE TPICGGKIKLYHPTGNIKSDKDIMFAKTLDFKSKKVL TGRKTIAVLDISVSYNRSMTTIHYNDDVDIDIHTDK NGKELCYCYITIDDHYLVD'VETIGVI'VNRSGKCLLV NNHLGIGIVKDKRISDSFGDVCMDTIFDFSEARELFS LTNDDNRNIAWDTDKLDDDTDIWTPVTEDDYKFLS RLVLYAKSQSDTVFDYYVLTGDTEPPTVFIFKVTRF YFNMPK SEQ ID VGF- AAO89489.1 MSMKYLMLLFAAMIIRSFADSGNAIETTSPEITNATT Outside NO:142 1/VACW DIPAIRLCGPEGDGYCLHGDCIHARDIDGMYCRCSH Deletion R210 GYTGIRCQHVVLVDYQRSENPNTTTSYIPSPGIMLV LVGIIIITCCLLSVYRFTRRTKLPIQDMWP SEQ ID VACWR AAO89490.1 MDEIVRIVRDSMWYIPNVFMDDGKNEGHVSVNNV Inside NO:143 211 CHMYFTFFDVDTSSHLFKLVIKHCDLNKRGNSPLHC Deletion YTMNTRFNPSVLIULLHHGMRNFDSKDEKGHHYQS ITRSLIY SEQ ID C20LJV AAO89491.1 MLFYLEEPIRGYVIILIVHPSWNDCATGHILIMLLNW Inside NO:144 ACWR2 HEQKEEGQHLLYLFIKHNQGYTLNILRYLLDRFDIQ Deletion 12 KDEYYNTAFQNCNNNVASYIGYDINLPTKDGIRLG V SEQ ID VACWR AAO89492.1 MLPHTSDTTSTFRLKTVFDLVFENRNIIYKADVVNDI Inside NO:145 213 IHHRLKVSLPMIKSLFYKMSLPTTITT Deletion SEQ ID VACWR AAO89493.1 MYDDLIEQCHLSMERKSKLVDKALNKLESTIGQSRL Outside NO:146 214 SYLPPEIMRNII Deletion SEQ ID B28R/V AAO89494.1 MKSVLYSYILFLSCIIINGRDIAPHAPSDGKCKDNEY Inside NO:147 ACWR2 KRHNLCPGTYASRLCDSKTNTQCTPCGSGTFTSRNN Deletion 15 HLPACLSCNGRRDRVTRLTIESVNALPDIIVFSKDHP DARHVFPKQNVE SEQ ID VACWR AAO89495.1 MDSLRPVVVVNWIQINFHIDIVKGITGYGFAFKGRD Outside NO:148 216 GVRKSETTRRTDDVSGYSVSYSTFCLGNTCLASG Deletion SEQ ID VACWR AAO89496.1 MWKLKIQLTTTTGLSESISTSELTITMNHKDCNPVF Outside NO:149 217 REEYFSVLNKVATSGFFTGERCAL Deletion SEQ ID B29R/V AA089497.1 MHVPASLQQSSSSSSSCTEEENKHHMGIDVIIKVTK Inside NO:150 AC2R2 QDQTPTNDKKQSVTEITESESDPDPEVESEDDSTSV Deletion 18(44% EDVDPPTTYYSIIGGGLRMNFGFTKCPQIKSISESAD 5′)  GNTVNARLSSVSPGQGKDSPAITHEEALAMIKDCEV SIDIRCSEEEKDSDIKTHPVLGSNISHKKVSYEDIIGST IVDTKCVKNLEFSVRIGDMCKESSELEVKDGFKYVD GSASEGATDDTSLIDSTKLKACV

TABLE 38 Examples of proteins encoded by Tian Tan Vaccinia genes  equivalent to those deleted in CopMD3p vector Protein SEQ ID Accession NO Gene ID Amino Acid SequenceLocation SEQ ID TF3L AAF34083.1 MNHCLLAISAVYFKAKWLTPFEKEFTSDYPFYVSPT Inside NO:151 (41% 3′) EMVDVSMMSMYGKAFNHASVKESFGNFSIIELPYV Deletion GDTSMMVILPDKIDGLESIEQNLTDTNFKIONCDFM DAMFIDVHIPKFKVTGSYNLVDTLVKSGLTEVFGST GDYSNMCNLDVSVDAMIHKTYIDVNEEYTEAAAA TCALVSDCASTITNEFCVDHPFIYVIRHVDGIULFVG RYCSPTTNC SEQ ID TB15R AAF34084.1 MTANFSTHVFSPQHCGCDRLTSIDDVKQCLTEYIYW Inside NO:152 SSYAYRNRQCAGQLYSTLLSFRDDAELVFIDIRELV Deletion KNMPWDDVKDCTEIIRCYIPDEQKTIREISAIIGLCA YAATYWGGEDHPTSNSLNALFVMLEMLNYVDYNII FRRMN SEQ ID ORFL AAF34085.1 MYNSSIHTPEYDVIIHVIEHLKHHKQCVQTVTSGMV NO:153 FTSPVSSSKTKSDDGRNLSDGFLLIRYITTDDFCTIF DIIPRHIFYQLANVDEH SEQ ID TB16R AAF34086.1 MELENEPVILPCPQINTLSSGYNILDILWEKRGADND Inside N0:154 RIIPIDNGSNMLILNPTQSDSGIYKITTNETYCDMMS Deletion LNLTIVSVLESNIDLISYPQIVNERSTGEMVCPNINAF IASNVNADIIWSGHRRLRNKRLKQRTPGIITIEDVRK NDAGYYTCVLEYIYRGKTYNVTRIVKLEVRDKIIPS TMQLPDGIVTSIGSNLTIACRVSLRPPTTDADVFWIS NGMYYEEDDGDGNGRISVANKIYMTDKRRVITSRL NINPVKEEDATTFTCMAFTIPSISKTVTVSIT SEQ ID ORFL AAF34087.1 MVIIPGVRCLSLLFLRRRCPLHIISAFTLLAINALILGH NO:155 TISPVDLSFTKGYEIRSIFDSKTDTIVKFNDIMSQ SEQ ID TB17L AAF34088.1 MSRKFMQVYEYDREQYLDEFIEDRYNDSFITSPEYY Inside NO:156 SAEKYMCRYTTLNHNCVNVRRCALDSKLLHDIITN Deletion CKINNIELVRATKFVYYLDLIKCNWVSKVGDSVL YPVIFITHTSTRNLDKVSVKTYKGVKVKKLNRCAD HAIVINPFVKFKLTLPNKTSHAKVLVTFCKLRTDITQ IEAPLSGNVLVYTFPNINKRIPGYIHVNIEGCIDGMIY INSSKFACVLKLHRSMYRIPPFPIDKSCCSQYTNGDI EIPIHDLIKDVAIFKNKETVYYLKLNNKTIARFTYFN NIDTAITQEHEYVKIALGIVCKLMINNMHSIVGVNH SNTFVNCLLEDNV SEQ ID TB18R AAF34089.1 MSRRLIYVLNINRESTHKIQENEIYTYFSHCNIDHTST Inside NO:157 ELDFVVKNYDLNRRHPVTGYTALHCYLYNNYFTN Deletion DVLKILLNHGVDVTMKTSSGRMPVYILLTRCCNISH DVVIDMIDKDKNHLLHRDYSNLLLEYIKSRYMLLK EEDIDENIVSTLLDKGIDPNFKQDGYTALHYYYLCL AHVYKPGECRKPMKKAKRIISLFIQHGANLNALDN CGNTPFHLYLSIEMCNNIHMTKMLLTFNPNFKKNN HGLTPILCYITSDYIQHDILVMLIHHYETNVGEMPID ERRIIVFEFIKTYSTRPADSITYLMNRFKNINIYTRYE GKTLLHVACEYNNTQVIDYLIR1NGDINALTDNNKH ATQLIIDNKENSPYTINCLLYILRYIVDKNVIRSLVDQ LPSLPIFDIKSFEKFISYCILLDDTFYDRHV1CNRNSKT YRYAFSKYMSFDKYDGIITKCHDETMLLKLSTVLDT TLYAVLRCHNSRKLRRYLTELKKYNNDKSFKIYSNI MNERYLNVYYKDMYVSKVYDKLFPVFTDKNCLLT LLPSEIIYEILYMLTINDLYNISYPPTKV SEQ ID TB19R AAF34090.1 MTMKMMVHIYFVSLSLLLLLFHSYAIDIENEITEFFN Inside NO:158 KMRDTLPAKDSKWLNPACMFGGTMNDIAALGEPF Deletion SAKCPPIEDSLLSHRYKDYVVKWERLEKNRRRQVS NKRVKHGDLWIANYTSKFSNRRYLCTVTTKNGDC VQGIVRSHIKKPPSCIPKTYELGTHDKYGIDLYCGIL YAKHYNNITWYKDNKEINIDDIKYSQTGKELIIHNPE LEDSGRYDCYVHYDDVRIKNDIVVSRCKILTVIPSQ DHRFKLILDPKINVTIGEPANITCTAVSTSLLIDDVLI EWENPSGWLIGFDFDVYSVLTSRGGITEATLYFENV TEEYIGNTYKCRGHNYYFEKTL1TTVVLE SEQ ID ORFR AAF34091.1 MHVIDVDVRLYMSTFIIIDQSTENTSIDTTVTINHYL NO:159 AIMIUIMNIIMMIMIELV SEQ ID TB21R AAF34092.1 LKNVECVDIDSTITFMKYDPNDDNKRTCSNWVPLT NO:160 NNYMEYCLVIYLETPKGGKIKLYHPTGNIKSDKDI MFAKTLDFKSTKVLTGRKTIAVLDISVSYNRSMTTI HYNDDVDIDIHTDKNGKELCYCYITIDDHYLVDVET IGVIVNRSGKCLLVNNHLGIGIVKDKRISDSFGDVC MDTIFDFSEARELFSLTNDDNRNIAWDTDKLDDDT DIWTPVTENDYKFLSRLVLYAKSQSDTVFDYYVLT GDTEPPTVFIFKVTRFYFNMPK SEQ ID TB22L AAF34093.1 MYCRCSHGYTGIRCQHVVLVDYQRSEKPNTTTSYIP NO:161 SPGIMLVLVGIIIITCCLLSVYRFTRRTKLPLQDMVVP SEQ ID TB23R AAF34094.1 MHVPASLQQSSSSSSSCTEEENKHHMGIDVIIKVTK Inside NO:162 (44% 5′)  QDQTPTNDKKQSVTEITESESDPDPEVESEDDSTSV Deletion EDVDPPTTYYSIIGGGLRMNFGFTKCPQIKSISESAD GNTVNARLSSVSPGQGKDSPAITHEEALAMIKDCEV SIDIRCSEEEKDSDIKTHPVLGSNISHKKVSYEDIIGST   VDTKCVKNLEFSVRIGDMCKESSELEVKDGFKYVD GSASEGATDDTSLIDSTKLKACV TB2OR ORFL

TABLE 39 Examples of proteins encoded by Wyeth Vaccinia genes equivalent to  those deleted in CopMD3p vector Protein SEQ ID Accession NO Gene ID Amino Acid Sequence Location SEQ ID VAC_D AEY74905.1 MNHCLLAISAVYFKAKWLTPFEKEFTSDYPFYVSPT Inside NO:163 PP20_20 EMVDVSMMSMYGKAFNHASVKESFGNFSHELPYV Deletion 7 GDTSMMVILPDKIDGLESIEQNLTDTNFKKWCDFM DAMFIDVHIPKFKVTGSYNLVDTLVKSGLTEVFGST GDYSNMCNLDVSVDAMIHKTYIDVNEEYTEAAAA TCALVSDCASTVTNEFCADHPFIYVIRHVDGKILFV GRYCSPTTNC SEQ ID VAC_D AEY74906.1 MTANFSTHVFSPQHCGCDRLTSIDDVKQCLTEYIYW Inside NO:164 PP10_20 SSYAYRNRQCAGQLYSTLLSFRDDAELVFIDIRELV Deletion 8 KHMPWDDVKDCAEIIRCYIPDEQKTIREISAIIGLCA YAATYWGGEDHPTSNSLNALFVMLEMLNYVDYNII FRRMN SEQ ID VAC_D AEY74907.1 MSILPVIFLSIFFYSSFVQTFNASECIDKGQYFASFME Inside NO:165 PP12_20 LENEPVILPCPQINTLSSGYNILDILWEKRGADNDRII Deletion 9 PIDNGSNMLILNPTQSDSGIYKITTNETYCDMMSLN LTIVSVSESNIDLISYPQIVNERSTGEMVCPNINAFIAS NVNADIIWSGHRRLIINKRLKQRTPGIITIEDVRKND AGYYTCVLEYIYGGKTYNVTRIVKLEVRDKIIPSTM QLPDGIVTSIGSNLTIACRVSLRPPTTDTDVFWISNG MYYEEDDGDGDGRISVANKIYMTDKRRVITSRLNI NPVKEEDATTFTCMAFTIPSISKTVTVSIT SEQ ID VAC_D AEY4908.1 MSRKFMQVYEYDREQYLDEFIEDRYNDSFITSPEYY Inside NO:166 PP20_21 SAEKYMCRYTTLNHNCVNVRRCALDSKLLHDIITN Deletion 0 CKIYNNIELVRATKFVYYLDLIKCNWVSKVGDSVL YPVIFITHTSTRNLDKVSVKTYKGVKVKKLNRCAD HAIVINPFVKFKLTLPNKTSHAKVLVTFCKLRTDITQ IEAPLSGNVLVYTFPDINKRIPGYIHVNIEGCIDGMIY INSSKFACVLKLHRSMYRIPPFPIDKSCCSQYTNDDI EIPIHDLIKDVAIFKNKETVYYLKLNNKTIARFTYFN NIDTAITQEHEYVKIALGIVCKLMINNMHSIVGVNH SNTFVNCLLEDNV SEQ ID VAC_D AEY74909.1 MSRRLIYVLNINRESTHKIQENEIYTYFSHCNIDHTST Inside NO:167 PP20_21 ELDFWKNYDLNRRQPVTGYTALHCYLYNNYFTN Deletion 1 DVLKILLNHGVDVTMKTSSGRMPVYILLTRCCNISH DVVIDMIDKDKNHLSHRDYSNLLLEYIKSRYMLLK EEDIDENIVSTLLDKGIDPNFKQDGYTALHYYYLCL AHVYKPGECRKPITIKKAKRIISLFIQHGANLNALDN CGNTPFHLYLSIEMCNNIHMTKMLLTFNPNFKKNN HGLTPILCYITSDYIQHDILVMLIHEIYETNVGEMPID ERRIIVFEFIKTYSTRPADSITYLMNRFKNINIYTRYE GKTLLHVACEYNNTHVIDYLIRINGDINALTDNNKH AIQLIIDNKENSPYTIDCLLYILRYIVDKNVIRSLVDQ LPSLPIFDIKSFEKFISYCILLDDTFYNRHVRNRNSKT YRYAFSKYMSFDKYDGIITKCHDETMLLKLSTVLDT TLYAVLRCHNSKKLRRYLNELKKYNNDKSFKIYSNI MNERYLNVYYKDMYVSKVYDKLFPVFTDKNCLLT LLPSEIIYEILYMLTINDLYNISYPPTKV SEQ ID VAC_D AEY74910.1 MTMKMMVHIYFVSLSLLLLLFHSYAIDIENEITEFFN Inside NO:168 PP20_21 KMRDTLPAKDSKWLNPACMFGGTMNDIATLGEPFS Deletion 2 AKCPPIEDSLLSHRYKDYVVKWERLEKNRRRQVSN KRVKHGDLWIANYTSKFSNRRYLCTVTTKNGDCV QGIVRSHIRKPPSCIPKTYELGTHDKYGIDLYCGILY AKHYNNITWYKDNKEINIDDIKYSQTGKKLIIHNPEL EDSGRYDCYVHYDDVRIKNDIWSRCKILTVIPSQD HRFKLKRNCGYASN SEQ ID VAC_D AEY74911.1 MRQIKINGTDMLTVMYMLNKPTKKRYVNNPIFTD Not NO:169 PP10_21 WANKQYKFYNQIIYNANKLIEQSKKIDDMIEEVSID Present 7 DNRLSTLPLEIRHL1FSYAFL SEQ ID VAC_D AEY74912.1 MSSKGGSGGMWSVFIHGHDGSNKGSKTYTSGGGG Outside NO:170 PP10_21 MWGGGSSSGVNGGVKSGTGKI Deletion 8 SEQ ID VAC_D AEY74913.1 MFDYLENEEVALDELKQMLRDRDPNDTRNQFKNN Outside NO:171 PP10_21 ALHAYLFNEHCNNVEVVKLLLDSGTNPLRKNWRQ Deletion 9 LPH SEQ ID VAC_D AEY74914.1 MLKLKDIAMALLEATGFSNINDFNIFSYMKSKNVD Outside NO:172 PP10_22 VDLIKVLVEHGFDLSVKCENHRSVIENYVMTMILFI Deletion 0 ENGCSVLYEDEY SEQ ID VAC_D AEY74915.1 MKGIDNTAYSYIDDLTCCTRGIMADYLNSDYRYNK Outside NO:173 PP10_22 DVDLVKLFLENGKPHGIMCSIVPLVVRNDKETIFLILK Deletion 1 TMNSDVLQHILIEYMTFGDIPLVEYGTWNKEAIHG YFRNINIDSYTMKYLL1UCEGRCHQLSRLDTYVNPT MDVIISTLIHTKRVFVTCLMLAQFLVL SEQ ID VAC_D AEY74916.1 MPSIISIGHLCKSNYGCYNFYTYTYKKGLCDMSYAC Outside NO:174 PP10_22 PILSTINKLPYLKDINMIDKRGETLLHKAVRYNKQS Deletion 2 LVSLLLESGSDVNIRSNNGYTCIAIAINESKNIELLKM LLCHKPTLDYVIDSLREISNIVDNDYAIKQCIKYAMII DDCTSSKIPEFISQRYNDYIDLCN SEQ ID VAC_D AEY49171.1 MKKIMVGGNTMFSLIFTDHGAIUIHRYANNPELREY Outside NO:175 PP10_22 YELKQNKIYVEAYDIISNAIVKHDRIHKTIESVDDNT Deletion 3 YISNLPYTIKYIUFEQQ SEQ ID VAC_D AEY74918.1 MRILFLIAFMYGCVHSYVNAVETKCSNLDIVTSSGE Outside NO:176 PP10_22 FHCSGCVEHMPNFSYMYWLAKDMRSDEDAKFIEH Deletion 4 LGEGIKEDETVRTIDGRIVTLQKVLHVTDTNKFAHY RFTCVLTTIDGVSKKNIWLK SEQ ID VAC_D AEY74919.1 MKLFTQNDRYFGLLDSCNHIFCITCINIWFIKTRRET Outside NO:177 PP10_22 GASDNCPKRTRFRNITMSKFYKLVN Deletion 5 SEQ ID VAC_D AEY74920.1 MHYPKYYINITKINPHLANQFRAWKKRIAGRDYMT Outside NO:178 PP10_22 NLSKDTGIQQSKLYVTVKKIETYMVYIYTTI Deletion 6 SEQ ID VAC_D AEY74921.1 MDIYDDKGLQTIKLFNNEFDCIRNDIRELFKHVTDS Outside NO:179 PP20_22 DSIQLPMEDNSDIIENIRKILYRRLKNVECVDIDNTIT Deletion 7 FMKYDPNDDNKRTCSNWVPLTNNYMEYCLVIYLE TPKGGKIKLYHPTGNIKSDKDIMFAKTLDFKSKKVL TGRKTIAVLDISVSYNRSITTIHYNDDVDIDIHTDKN GKELCYCYITIDDHYLVDVETIGVIVNRSGKCLLVN NHLGIGIVKDKRISDSFGDVCMDTIFDFSEARELFSL TNDDNRNIAWDTDKLDDDTDIWTPVTENDYKFLSR LVLYAKSQSDTVFDYYVLTGDTEPPTVFIFKVTRFy FNMFK SEQ ID VAC_D AEY74922.1 MLINYLMLLFAAMIIRSFADSGNAIETTLPEITNATT Outside NO:180 PP20_22 DIPAIRLCGPEGDGYCLHGDCIHARDIDGMYCRCSH Deletion 8 GYTGIRCQHVVLVDYQRSEKPNITTSYIPSPGIMLV LVGIIIITCCLLSVYRFTRRTNKLPLQDMVVP SEQ ID VAC_D AEY74923.1 MDIFKELIVKHPDENVLISPVSILSTLSILNHGAAGST Outside NO:181 PP20_22 AEQLSKYIENMNENTPDDIUCDDNNDMDVDIPYCAT Deletion 9 LATANKIYGSDSIEFHASFLQKIKDDFQTVNFNNAN QTKELINEWVKTMTNGKINSLLTSPLSINTRMTVVS AVHFKAMWKYPFSKHLTYTDKFYISKNIVTSVDMM VGTENNLQYVHINELFGGFSIIDIPYEGNSSMVIILPD DIEGIYNIEKNITDEKFIUCWCGMLSTKSIDLYMPKF KVEMTEPYNLVPILENLGLTNIFGYYADFSKMCNET ITVEKFLHTTFIDVNEEYTEASAVTGVFMTNFAMVY RTKVYINHPFMYMIKDTTGRILFIGKYCYPQ MMIYGLIACLIFVTSSIASPLYIPVIPPITEDKSFNSVE Outside SEQ ID C13L/V AEY74924.1 VLVSLFRDDQKDYTVISQFNNYTIDTKDWTIGVLST Deletion NO:182 AC_DPP PDGLDIPLTNITYWSRFTIGRALFKSESEDIFQKKMSI 20_230 LGVSIECKKSSTLLTFLTVRKMTRVFNKFPDMAYYR GDCLKAVYVTMTYKNTKTGETDYTYLSNGGLPAY YRNGVDG SEQ ID VAC_D AEY74925.1 MNLQKLSLAIYLTATCSWCYETCIRKTALYHDIQLE Outside NO:183 PP20_23 HVEDNKDSVASLPYK Deletion 1 SEQ ID VAC_D AEY74926.1 MSLESFIITITNNNSSTNIDNMCHLYVKVCPSSLLFR Inside NO:184 PP20_23 LFVECCDINKLVEGTTPLHCYLMNEGFESSVLKNLL Deletion 2 KEYVMTSITQIFNS SEQ ID VAC_D AEY74927.1 MISLSFLIHNPLKKWKLKPSISINGYRSTFTMAFPCA Inside NO:185 PP20_23 QFRPCHCHATKDSLNTVADVRHCLTEYILWVSHRW Deletion 3 THRETAGPLYRLLISFRIDATELFGGELKDSLPWDNI DNCVEIIKCFIRNDSMKTAEELRAIIGLCTQSAIVSGR VFNDKYIDILLMLRKILNENDYLTLLDHIRTAKY SEQ ID VAC_D AEY74928.1 MIAFIIFREIGHSTRIAMDCTCILCRLLDEDVTYKKIK Inside NO:186 PP20_23 LEIETCHNLSKIIIDRAGNNALHCYVFNKCDTDIKIV Deletion 4 RLLLSRGVERLCANNEGLTPLGVYSKHRYVKSQIVH LLISSYSNSSNELKSNINDFDLSSDNIDLRLLKYLIVD KRIRPSKNTNYAINSLGLVDIYVTTPNPRPEVLLWLL KSECYSTGYVFRTCMYNSDMCKNSLHYYISSHRES QSLSKDVIKCLINNNVSIHGRDEGGSLPIQYYWSFST IDIEIVKLLLIKDVDTCRVYDVSPILEAYYLNKRFRV TPYNVDMEIVNLLIERRHTLVDVMRSITSYDSREYN HYHDNILKRFRQQDESIVQAMLINYLHYGDMVVRC MLDNGQQLSSARLLC SEQ ID VAC_D AEY74929.1 MYGLILSRFNNCGYHCYETILIDVFDILSKYMDNID Inside NO:187 PP20_23 MIDNENKTLLYYAVDVNNIQFAKRLLEYGASVTTS Deletion 5 RSIINTAIQKSSYRRENKTKLVDLLLSYHPTLETMID AFNRDIRYLYPEPLFACIRYALILDDDFPSKVKYDIS GRHKELKRYRVDINRMKNAYISGVSMFDILFKRSK RHRLRYAKNPTSNGTKKN SEQ ID VAC_D AEY74930.1 MSRINITKKIYCSVFLFLFLSYISNYEKVNDEMYEMG Inside NO:188 PP20_23 EMDEIVSIVRDSMWYIPNVFMDDGKNEGHVSVNNV Deletion 6 CHMYFTFFDVDTSSHLFKLVIKHCDLNKRGNSPLHC YTMNTRFNPSVLKILLHHGMRNFDSKDDHYQSITRS LIY SEQ ID VAC_D AEY74931.1 MEQTLTRLHTYLQQYTKHSPRVVYALLSRGYVIILI Inside NO:189 PP20_23 VHPSWNDCATGHILIMLLNWHEQKEEGQHLLYLFI Deletion 7 KHNQGYTLNILRYLLDRFDIQKDEYYNTAFQNCNN NVASYIGYDINLPTKDGIRLGV SEQ ID VAC_D AEY74932.1 MLPHTSDTTSTFRLKTVFDLVFENRNIIYKADVVNDI Inside NO:190 PP20_23 IHHRLKVPMIKSLFYKMSEFSPYDDYYVKKILAYCL Deletion 8 LRDESFAELHSKFCLNEDYKSVFMKNISFDKIDSIIV T SEQ ID VAC_D AEY74933.1 MHHPMESVKTTNTNAIKVREHTLPDYANTQCTPC Inside NO:191 PP20_23 GSGTFTSRNNHLPACLSCNGRRDRVTLLTIESVNAL Deletion 9 PDIIVFSKDHPDARHVFPKQNVE SEQ ID VAC_D AEY74934.1 MHVPASLQQSSSSCTEEENKHHMGIDVIIKVTKQDQ Inside NO:192 PP20-24 TPTNDKKQSVTEITESESDPDPEVESEDDSTSVEDV Deletion 1(43% DLPTTYYSIIGGGLRMNFGFIXCPQIKSISESADGNT 5′) VNARLSSVSPGQGKDSPAITHEEALAMIKDCEVSIDI RCSEEEKDSDIKTHPVLGSNISHKKVSYEDIIGSTIVD TKCVKNLEFSVRIGDMCKESSELEVKDGFKYVDGS ASEGATDDTSLIDSTKLKACV SEQ ID VAC_D AEY74919.1 MKLFTQNDRYFGLLDSCNHIFCITCINIVVHKTRRET Outside NO:193 PP10_22 GASDNCPKRTRFRNITMSKFYKLVN Deletion 5 SEQ ID VAC_D MHYPKYYINITKINPHLANQFRAVVKKRIAGRDYMT Outside NO:194 PP10_22 AEY74920.1 NLSKDTGIQQSKLYVTVKKIETYMVYIYTTI Deletion 6 SEQ ID VAC_D AEY7492.1 MDIYDDKGLQTIKLFNNEFDCIRNDIRELFKHVTDS Outside NO:195 PP20_20 DSIQLPMEDNSDIIENIRKILYRRLKNVECVDIDNTIT Deletion 7 FMKYDPNDDNKRTCSNWVPLTNNYMEYCLVIYLE TPKGGKIKLYHPIGNIKSDKDIMFAKTLDFKSKKVL TGRKTIAVLDISVSYNRSITTIHYNDDVDIDIHTDKN GKELCYCYITIDDHYLVDVETIGVIVNRSGKCLLVN NHLGIGIVKDKRISDSFGDVCMDTIFDFSEARELFSL TNDDNRNIAWDTDKLDDDTDIWTPVTENDYKFLSR LVLYAKSQSDTVFDYYVLTGDTEPPTVFIFKVTRFY FNMPK SEQ ID VAC_D  AEY74922.1 MLINYLMLLFAAMIIRSFADSGNAIETTLPEITNATT Outside NO:196 PP20:22 DIPAIRLCGPEGDGYCLHGDCIHARDIDGMYCRCSH Deletion 8 GYTGIRCQHVVLVDYQRSEKPNTTTSYIPSPGIMLV LVGIIIITCCLLSVYRFTRRTN1KLPLQDMVVP SEQ ID VAC_D AEY74933.1 MHHPMESVKTTNTNAIKVREHTLPDYANTQCTPC Inside NO:197 PP20_23 GSGTFTSRNNHLPACLSCNGRRDRVTLLTIESVNAL Deletion 9 PDIIVFSKDHPDARHVFPKQNVE SEQ ID VAC_D AEY74934.1 MHVPASLQQSSSSCTEEENKHHMGIDVIIKVTKQDQ Inside NO:198 PP20-24 TPTNDKKQSVTEITESESDPDPEVESEDDSTSVEDV Deletion 1(43% DLPTTYYSIIGGGLRMNFGFTKCPQIKSISESADGNT 5′) VNARLSSVSPGQGKDSPAITHEEALAMIKDCEVSIDI RCSEEEKDSDIKTHPVLGSNISHKKVSYEDIIGSTIVD TKCVKNLEFSVRIGDMCKESSELEVKDGFKYVDGS ASEGATDDTSLIDSTKLKACV

TABLE 40  Examples of proteins encoded by Lister Vaccinia genes equivalent to  those deleted in CopMD3p vector Protein SEQ ID Accession NO Gene ID Amino Acid Sequence Location SEQ ID B15RfLi ABD52695.1 MTANFSTHVFSPQHCGCDRLTSIDDVKQCLTEYIYW Inside NO:200 st191 SSYAYRNRQCAGQLYSTLLSFRDDAELVFIDIRELV Deletion KNMPWDDVKDCTEIIRCYIPDEQKTIREISAIIGLCA YAATYWGGEDHPTSNSLNALFVMLEMLNYVDYNII FRRMN SEQ ID List192 ABD52696.1 MSILPVIFLPIFFYSSFVQTFNAPECIDKGQYFASFME Inside NO: 201 LENEPVILPCPQINTLSSGYNILDILWEKRGADNDRII Deletion PIDNGSNMLILNPTQSDSGIYKITTNETYCDMMSLN LTIVSVSESNIDLISYPQIVNERSTGEMVCPNINAFIAS NVNADIIWSGHRRLRNKRLKQRTPGIITIEDVRKND AGYYTCVLEYIYRGKTYNVTRIVKLEVRDKIIPSTM QLPDGIVTSIGSNLTIACRVSLRPPTTDADVFWISNG MYYEEDDGDGNGRISVANKIYMTDKRRVITSRLNI SEQ ID B17L/Lis ABD52698.1 NPVKEEDATTFTCMAFTIPSISKTVTVSIT Inside NO:202 t193 MSRKFMQVYEYDREQYLDEFIEDRYNDSF1TSPEYY Deletion SAEKYMCRYTTLNHNCINVRRCALDSKLLHDIITNC KIYNNIELVRATKFVYYLDLIKCNWVSKVGDSVLYP VIFITHTSTRNLDKVSVKTYKGVKVKKLNRCADHAI VINPFVKFKLTLPNKTSHAKVLVTFCKLRTDITQIEA PLSGNVLVYTFPDINKRIPGYIHVNIEGCIDGMIYINS SKFACVLKLHRSMYRIPPFPIDKSCCSQYTNDDIEIPI HDLIKDVAIFKNKETVYYLKLNNKTIARFTYFNNID TAITQEHEYVKIALGIVCKLMINNMHSIVGVNHSNT FVNCLLEDNV SEQ ID crmE/Lis ABD52700.1 MTKVIIILGFLIINTNSLSMKCEQGVSYYNSQELKCC Not NO:203 t195 KLCKPGTYSDHRCDKYSDTKGHCPSDTFTSIYNRSP Present WCHSCRGPCGTNRVEVTPCTPTTNRKHCDSNSYCL LKASDGNCVTCAPKTKCGRGYGKKGEDEMGNTK KKCRKGTYSDIVSDSDQCKPMTR SEQ ID L6/List1 ABD52701.1 MAMPSLSACSSIEDDFNYGSSVASASVHIRMAFLRK Not NO:204 96 VYGILCLQFLLTTATTAVFLYFDCMRTFIQGSPVLIL Present ASMFGSIGLIFALTLHRHKHPLNLYLLCGFTLSESLT LASVVTFYDVHVVMQAFMLTTAAFLALTTYTLQSK RDFSKLGAGLFAALWILILSGLLGIFVQNETVKLVLS AFGALVFCGFIIYDTHSLIHKLSPEEYVLASINLYLDII NLFLHLLQLLEVSNKK SEQ ID List197 ABD52704.1 MASPCAKFRPCHCHATKDSLNTVADVRHCLTEYIL Inside NO:205 WVSHRWTHRESAGSLYALLISFRTDATELFGGELKD Deletion SLPWDNCVEIIKCFIRNDSMKTAEELRAIIGLCTQSAI VSGRVFNDKYIDILLMLRKILNENDYLTLLDHIRTA KY SEQ ID List199C ABD52706.I MEQTLTRLHTYLQQYTKHSPRVVYALLSRGYVIILI Inside NO:206 VHPSWNDCATGHILIMLLNWHEQKEEGQHLLYLFI Deletion KHNQGYTLNILRYLLDRFDIQKDEYYNTAFQNCNN NVASYIGYDINLPTKDGIRLGV SEQ ID List199D ABL63830.1 MLPHTSDTTSTFRLKTVFDLVFENRNIIYKADVVNDI Inside NO:207 IHHRLKVSLPM1KSLFYKMSLPTTITT Deletion SEQ ID C23L/Lis ABL63827.1 MKQYIVLACMCLAAAAMPASLQQSSSSSSSCTEEE Inside NO:208 t201 NKHHMGIDVIIKVTKQDQTPTNDKKQSVTEITESES Deletion (47% 5′) DPDPEVESEDDSTSVEDVDPPTTYYSIIGGGLRMNF GFTKCPQIKSISESADGNTVNARLSSVSPGQGKDSPA ITHEEALAMIKDCEVSIDIRCSEEEKDSDIKTHPVLGS NISHIUCVSYEDIIGSTIVDTKCVKNLEFSVRIGDMCK ESSELEVKDGFKYVDGSASEGATDDTSLIDSTKLKA CV List198 A List198 B List199 A List199 B List200 List194

EXAMPLES

The following examples are put forth so as to provide those of ordinary skill in the art with a description of how the compositions and methods claimed herein are performed, made, and evaluated, and are intended to be purely exemplary of the invention and are not intended to limit the scope of what the inventor regards as her invention.

Example 1—Creation Of the CopMDp3p “SKV-B8R+” Recombinant Orthopoxvirus

The open reading frames (ORFs) from 59 poxvirus strains were clustered into orthologs and aligned at the amino acid level (see FIG. 1 for phylogenetic analysis). Bayesian analysis was performed to determine relatedness of all strains. Poxviruses are very diverse in gene content and host range. There are several naturally occurring Vaccinia wild-type strains, which are different from one another.

Five Vaccinia wild type strains (Copenhagen, TianTan, Lister, Wyeth, and Western Reserve) were mixed at equal plaque forming unit counts and sequenced with NGS (Input pool). The resulting mixture was passaged three times in different cancer cell lines (HeLa, 786-0, HT29, MCF7). The final population was sequenced with NGS illumina sequencing. Reads (short DNA fragments) were assigned to various strains based on sequence identity and used to calculate the percent of each strain in the final population. The relative abundance of the different viral strains was then quantified. As shown in FIG. 2, the Copenhagen strain was the most abundant vaccinia strain after three passages in any of the four cancer cell lines indicating that this strain was able to outgrow other strains and therefore replicates faster.

Different Vaccinia wild type strains were also used to infect at low PFU (1×10⁴) various patient tumor cores. Each strain infected on average 4 replicates each containing three 2×2 mm tumor cores. Replication was assessed through virus titering and is expressed as plaque forming units (PFU) as shown in FIG. 3. The Copenhagen strain grows to higher titers than other strains and therefore replicates faster in patient ex-vivo samples. Patient ex-vivo cores are a good mimic of a patient's 3D tumor.

Vaccinia wild-type strains were then subjected to a plaque assay on U2-OS cells with a 3% CMC overlay. Two days past infection, 20-30 plaques for each strain were measured for their size. Plaque size measurements for Copenhagen, Western Reserve, Wyeth, Lister, and Tian Tan are shown in FIG. 4. Plaque formation is affected by the ability of the virus to replicate, spread, and kill. The larger plaque sizes observed for the Copenhagen strain suggest that this strain is superior in these abilities, which are important for the development of an oncolytic virus.

Then, the number of TTAA sites across 1 kb regions in Vaccinia Copenhagen genome were counted (see FIG. 5A). llumina NGS sequencing was combined and used to identify Transposon Insertion Sites (Tn-Seq). The input library was passaged three times in either HeLa or U2-OS cells after which frequencies of transposon knockouts were determined. The frequency of a knockout directly corresponds to the amount of reads supporting the event (see FIG. 5B and FIG. 6).

Finally, all 59 poxvirus genomes from FIG. 1 were used to find ORFs and clustered into orthologous groups. Groups containing Copenhagen genes were plotted based on location of the gene in the Copenhagen genome (x-axis) and size of the group (y-axis). When all 59 species share the same gene the conservation is considered to be 100%. The TTAA motif is required for a transposon insertion and this motif is ubiquitous along the genome, meaning transposons can insert anywhere in the genome. However, it was noted that transposons insert preferentially in areas of low poxvirus gene conservation. While sequencing transposon knockouts, major deletions were identified and labelled as CopMD5p and CopMD3p (see FIG. 5C and FIG. 6). Genes that are present in the middle of the genome and that have an elevated gene conservation (FIG. 5C) are important for viral replication. This is because knocking these genes out with transposon insertions causes a decrease in fitness (less frequency after passaging). Genes that are part of the major deletions CopMD5p and CopMD3p were found to be less important for viral replication as their deletion does not impact fitness.

Illumina NGS deep sequencing revealed presence of major deletions during the plaque purification process. CopMD5p and CopMD3p represent clones, which were plaque purified and found to harbor major genomic deletions. These 2 clones were used to co-infect a monolayer of HeLa cells at a high MOI (MOI 10) to induce recombination. Random plaque picking and PCR revealed presence of a double deleted CopMD5p3p which contained both genome deletions (see FIG. 8). These 2 deletions were combined and purified to give a replicating virus, referred to herein as “CopMD5p3p”, that exhibits deletions in the C2L, C1L, N1L, N2L, M1L, M2L, K1L, K2L, K3L, K4L, K5L, K6L, K7R, F1L, F2L, F3L, B14R, B15R, B16R, B17L, B18R, B19R, and B20R genes, as well as single deletions in each of the ITR genes B21R, B22R, B23R, B24R, B25R, B26R, B27R, B28R, and B29R. As used herein, “CopWT” refers to wild-type Copenhagen vaccinia virus, “CopMD5p” refers to a Copenhagen vaccinia virus harboring deletions in representative 5′ genes (C2L, C1L, N1L, N2L, M1L, M2L, K1L, K2L, K3L, K4L, K5L, K6L, K7R, F1L, F2L, F3L), and “CopMD3p” refers to a Copenhagen vaccinia virus harboring deletions in representative 3′ genes (B14R, B15R, B16R, B17L, B18R, B19R, and B20R) as well as single deletions in each of the ITR genes B21R, B22R, B23R, B24R, B25R, B26R, B27R, B28R, and B29R.

The 59 poxvirus genomes were then assessed for the presence of these 32 genes deleted in the CopMD5p3p. Homology searches were used to query poxviruses from other clades with amino acid sequences of Table 2 genes from the Copenhagen genome. As shown in FIG. 35, the percentage of these 32 genes present in various poxvirus strains decreases with increasing divergence from the Copenhagen strain (each dot on the plot represents one poxvirus genome). However, a majority of the members of the orthopox family, comprise at least 85% of the the genes which are deleted in the CopMD5p3p recombinant vector.

Example 2—Cancer Cell Death

Cancer cells were infected with CopMD5p3p at a range of MOIs (1 to 0.01) in 24-well plates in 4 replicates. Two days post infection with virus, plates were stained with crystal violet. Crystal violet stain was dissolved into SDS and read by spectrophotometry. Data is represented as percent of non-infected cells (see FIG. 9). This data shows that the majority of cancer cell lines die faster when exposed to the CopMD5p3p virus.

The ability of wild-type Copenhagen vaccinia virus and several modified Copenhagen vaccinia virions to induce an anti-tumor immune response and to propagate in various cancer cell lines is also shown in FIGS. 26, 27, and 29-34.

Example 3—Growth in Cancer Cells

Four cancer cell lines were infected with CopMD5p3p at a low MOI (0.001) in 24-well plates in triplicates, and at different time points, the virus was collected and tittered. Time 0 h represents input. The growth curves of HeLa, 786-0, HT-29, and MCF7 are shown in FIG. 10. This data shows that the modified CopMD5p3p virus is not impaired in its ability to grow in vitro. This means that the virus is replication competent, even in presence of interferon response. The ability to replicate in mammalian cell lines provides another important advantage. As such, viruses may be manufactured with enhanced speed and efficiency.

Example 4—Growth in Patient Tumor Samples

Patient tumor samples were obtained immediately after surgery and cut into 2 mm×2 mm cores. Three cores were infected with a small amount of virus (1×10⁴ PFU), either wild-type Copenhagen or CopMD5p3p. After 72h virus output was assessed by plaque assay and final Viral Titer expressed as PFU (see FIG. 11). This data shows that the modified CopMD5p3p virus can replicate in fresh patient tumor samples. Replication in patient tumor samples is a good model of replication in a patient 3D tumor.

Example 5—Syncytia in U2-OS Cells

Monolayers of U2-OS cells were infected with either Copenhagen wild-type or CopMD5p3p virus. After 2h, the media was changed for overlay media as done for a plaque assay. At 48h post infection, pictures were taken with EVOS to assess plaque phenotype (see FIG. 12). Cell fusion, also known as syncytia, is thought to help the virus spread, since uninfected cells merge with infected cells. Additionally, it has been shown that fused cells are immunogenic and in the case of cancer cells can help initiate an anti-tumor immune response. See, e.g., http://cancerres.aacrjournals.org/content/62/22/6566.long.

Example 6—Syncytia in 786-O Cells

Monolayers of 786-O cells were infected with either Copenhagen wild-type or CopMD5p3p virus. After 24h pictures were taken with EVOS at 10× magnification (see FIG. 13). This is additional evidence for the occurrence of syncytia. In FIG. 12, the phenotype of a plaque is shown. In the current experiment, monolayers of cells were infected without overlay. Most cells infected by the CopMD5p3p virus have fused.

Example 7—Tumor Control and Weight Loss in Mouse Model

Nude CD-1 (Crl:CD1-Foxn1nu) mice were seeded with HT-29 human colon cancer xenograft (5e6 cells). Once subcutaneous tumours have established an approximate 5 mm×5 mm size, mice were treated three times (dashed lines) 24h apart with 1×10⁷ PFU of either vaccinia virus intravenously. Mice were measured approximately every other day for tumor size and weight loss (see FIG. 14). This experiment shows that CopMD5p3p is a much safer virus because it does not cause any weight loss or other signs of sickness in immunocompromised nude mice. This experiment also shows CopMD5p3p is able to control tumor growth similarly to the parental Copenhagen wild-type virus.

Example 8—Pox Lesion Formation

Nude CD-1 mice were treated once with 1×10⁷ PFU of either vaccinia virus intravenously, six mice per group. Two weeks post treatment, mice were sacrificed and pictures of tails were taken. Pox lesions on tails were counted manually on every mouse tail. Representative pictures shown in FIG. 15. This experiment shows that CopMD5p3p is a much safer virus because it does not cause any pox lesions in immunocompromised nude mice. This is important since prior Oncolytic Vaccinia clinical data has shown patients developing pox lesions upon treatment. Knockout of thymidine kinase (TK) is a popular way of increasing the safety of an OV (oncolytic virus), currently present in a Phase III Oncolytic Vaccinia and in FDA approved Oncolytic T-Vec. The data shows that deleting TK does not play a crucial role in this assay, where mice develop pox lesions when challenged with TK deleted viruses, but do not develop pox lesions with CopMD5p3p which has an intact TK.

Example 9—IVIS Bio-Distribution of Vaccinia after Systemic Administration

Vaccinia viruses wild-type Wyeth, wild-type Copenhagen, and CopMD5p3p were engineered to express Firefly Luciferase (Fluc) and YFP through transfection of infected cells with a pSEM1 plasmid replacing TK with Fluc and YFP. Viruses were plaque purified and expanded. All viruses are TK knockouts and encode functional Fluc in their TK locus.

Nude CD-1 mice were then seeded with HT-29 human colon cancer xenograft. Once subcutaneous tumors have established an approximate 5 mm×5 mm size, mice were treated once with 1e7 PFU of either vaccinia Fluc encoding virus intravenously, four mice per group. Four days post treatment, mice were injected i.p. (intraperitoneal) with luciferin and imaged with IVIS for presence of virus (see FIG. 16). This experiment shows that CopMD5p3p is a much safer virus because it is more specific to the tumor. Other viruses show off target replication in the tail, muscle, paws and intra-nasal cavity. CopMD5p3p is only localized in the tumor. As shown in previous FIGS. 15 and 16, there is less detectable CopMD5p3p in the tail compared to the other strains. FIG. 17 shows that CopMD5p3p also has lower titers in other organs when compared to other oncolytic Vaccinia. Since the CopMD5p3p replicates at the same level as the other viruses in the tumor but less in off-target tissues, CopMD5p3p fits the profile of an oncolytic virus better.

An additional example of the biodistribution of various vaccinia viral vectors, including the wild-type Copenhagen vaccinia virus and several modified Copenhagen vaccinia virions, is shown in FIG. 28.

Example 10—Immunogenicity of Vaccinia in Human PBMCs

PBMCs were isolated from blood of healthy human donors (n=2). PBMCs were incubated with either Vaccinia for 24h and checked for early activation markers using Flow Cytometry (see FIG. 18). This experiment shows that CopMD5p3p is more immunogenic and more readily detectable by immune cells. We believe that this is a desirable trait, since OVs replicating in tumor tissue need to activate immune cells for a successful anti-tumor immune response.

Example 11—Immunogenicity of Vaccinia in Mouse Splenocytes

Immune competent Balb/C mice were injected with 1×10⁷ Vaccinia PFU Vaccinia virus intravenously. After one or two days, mice were sacrificed, spleens were harvested and analyzed for immune activation using Flow Cytometry (see FIG. 19). This experiment shows that CopMD5p3p is more immunogenic and more readily detectable by mouse immune cells. This data complements nicely the previous FIG. 18, since most of the in vivo experiments are done in mice.

Example 12—Immunogenicity of Vaccinia in Human Cells

Human cancer cells 786-O were infected at an MOI of 0.01 with either virus. The next day, cells were harvested and nuclei and cytoplasm were separated by cell fractionation. Protein was extracted from each fraction and blotted for NF-kB subunits p65 and p50 (see FIG. 20). NF-kB immune transcription factor initiated an immune response once its subunit p65 and p50 are translocated to the nucleus. Some viruses are immunosuppressive and block this translocation, preventing an immune response. Suppressing NF-kB function is counter-intuitive to the goal of using oncolytic viruses in combination with immunotherapeutic approaches. Thus, CopMD5p3p is a more advantageous virus as it behaves similarly to MG-1.

Example 13—Synergy with Immune Checkpoint Inhibitor Anti-CTLA4 in Aggressive Melanoma Model

Immune competent C57BL/6 mice were seeded (5e5 cells) subcutaneously with B16-F10 melanoma tumors. Treatment began once subcutaneous tumors have established an approximate 5 mm×5 mm size. Mice treated with CopMD5p3p virus received three 1×10⁷ PFU doses into the tumor (intra-tumor) one day apart. Mice treated with anti-CTLA4 received five 100 μg doses of antibody i.p. one day apart. Survival were recorded every other day once treatment started (see FIG. 21). In this experiment, we tested if the oncolytic effect of our CopMD5p3p virus can synergize with blockade of a well-known immune checkpoint CTLA-4 in a very aggressive melanoma murine model. Surprisingly, the median survival of mice treated with virus and checkpoint was higher than any other group. This suggests that CopMD5p3p has some stimulating properties that synergize with checkpoint blockade immunotherapy.

Example 14—Synergy with Immune Checkpoint Inhibitor Anti-CTLA4

Immune competent Balb/C mice were seeded (5×10⁵ cells) subcutaneously with CT26-LacZ tumors. Treatment began once subcutaneous tumors have established an approximate 5 mm×5 mm size. Mice treated with Vaccinia virus received three (24h apart, first three dashed lines) 1e7 PFU doses into the tumour (intra-tumour). Mice treated with Anti-CTLA4 received five (24h apart, dashed lines) 100 μg doses of antibody i.p. Tumor size and survival were recorded every other day once treatment started (see FIG. 22). The data shows that a TK knockout Vaccinia virus does not work as well with Anti-CTLA4 as does CopMD5p3p. This suggests CopMD5p3p is more immunogenic and more capable of generating an anti-tumour immune response.

Example 15—Synergy with Immune Checkpoint Inhibitor Anti-PD1

Immune competent Balb/C mice were seeded (5×10⁵ cells) subcutaneously with CT26-LacZ tumors. Treatment began once subcutaneous tumors have established an approximate 5 mm×5 mm size. Mice treated with Vaccinia virus received three (24h apart, first three dashed lines) 1e7 PFU doses into the tumor (intra-tumor). Mice treated with Anti-PD1 received five (24h apart, last five dashed lines) 100 μg doses of antibody i.p. 24h after the last dose of Vaccinia virus. Tumor size and survival were recorded every other day once treatment started (see FIG. 23). The data shows that a TK knockout Vaccinia virus does not work as well with Anti-PD1 as does CopMD5p3p. This suggests CopMD5p3p is more immunogenic and more capable of generating an anti-tumor immune response.

Example 16—Synergy with Immune Checkpoint Inhibitor Anti-PD1 and Anti-CDLA4

Immune competent Balb/C mice were seeded (5×10⁵ cells) subcutaneously with CT26-LacZ tumors. Treatment began once subcutaneous tumors have established an approximate 5 mm×5 mm size. Mice treated with Vaccinia virus received three (24h apart, first three dashed lines) 1×10⁷ PFU doses into the tumor (intra-tumor). Mice treated with Anti-CTLA4 received five (24h apart, first five dashed lines) 100 μg doses of antibody i.p. Mice treated with Anti-PD1 received five (24h apart, last five dashed lines) 100 μg doses of antibody i.p. 24h after the last dose of Vaccinia virus. Tumor size and survival were recorded every other day once treatment started (see FIG. 24). In this experiment we tested whether a lower dose (25 μg instead of 100 μg) of checkpoint inhibitor antibody could work if we blocked both checkpoints simultaneously. The CopMD5p3p still managed to achieve cures in this murine model with a lower dose (50 μg total) of both inhibitors of checkpoints. Since checkpoint inhibitors have dose dependent toxicity, it is advantageous that very small doses of checkpoint blockers can still achieve an observable phenotype. As in other experiments, the CopMD5p3p virus manages to cure established tumors, and this effect is not observed with wild-type virus lacking the corresponding deletions of CopMD5p3p.

Example 17—Administration for the Treatment of a Subject

Using the methods described herein, a clinician of skill in the art can administer to a subject (e.g., a patient) a pharmaceutical composition containing a recombinant orthopoxvirus vector described herein to treat cancer or tumor cells. The cancer may be, for example, leukemia, lymphoma, liver cancer, bone cancer, lung cancer, brain cancer, bladder cancer, gastrointestinal cancer, breast cancer, cardiac cancer, cervical cancer, uterine cancer, head and neck cancer, gallbladder cancer, laryngeal cancer, lip and oral cavity cancer, ocular cancer, melanoma, pancreatic cancer, prostate cancer, colorectal cancer, testicular cancer, or throat cancer, among others.

For instance, a clinician of skill in the art may assess that a patient is suffering from cancer or tumors and may administer to the patient a therapeutically effective amount (e.g., an amount sufficient to decrease the size of the tumor) of a pharmaceutical composition containing the recombinant orthopoxvirus vector disclosed herein. The pharmaceutical composition may be administered to the subject in one or more doses (e.g., 1, 2, 3, 4, 5, 6, 7, 8, 9, 10, 15, 20, 25, or more) per a specified time interval (e.g., weekly, daily, or hourly). The patient may be evaluated between doses to monitor the effectiveness of the therapy and to increase or decrease the dosage based on the patient's response. The pharmaceutical composition may be administered to the patient orally, parenterally (e.g., topically), intravenously, intramuscularly, subcutaneously, or intranasally. The treatment may involve a single dosing of the pharmaceutical composition. The treatment may involve continued dosing of the pharmaceutical composition (e.g., days, weeks, months, or years). The treatment may further involve the use of another therapeutic agent (e.g., an immune checkpoint inhibitor, such as an anti-PD-1 or anti-CTLA-4 antibody or antigen-binding fragment thereof, IL-12, FLT3L).

Example 18—Targeted Deletions of CopMD5p and CopMD3p

The following protocol for producing modified vaccinia viral vectors utilizes techniques described, e.g., in Rintoul et al. PLoS One. 6(9): e24643 (2011), the disclosure of which is incorporated herein by reference.

Briefly, CopMD5p (Copenhagen vaccinia virus harboring deletions in 5′ genes: C2L, C1L, N1L, N2L, M1L, M2L, K1L, K2L, K3L, K4L, K5L, K6L, K7R, F1L, F2L, F3L) and CopMD3p (Copenhagen vaccinia virus harboring deletions in 3′ genes: (B14R, B15R, B16R, B7L, B18R, B19R, and B20R as well as single deletions in each of the ITR genes B21R, B22R, B23R, B24R, B25R, B26R, B27R, B28R, and B29R targeting recombinant constructs were synthesized by g-Block technology (IDT, Coralville Iowa). U2OS cells were infected with wildtype vaccinia virus (Wyeth, Western Reserve, Tian Tan, Lister) at an MOI of 0.01 in serum free DMEM for 1.5 hours. Viral supernatant was aspirated and U2OS cells were transfected with PCR amplified CopMD5p or CopMd3p targeting g-Blocks by Lipofectamine 2000 (Invitrogen) in OptiMEM (Gibco). DMEM supplemented with 10% FBS was added to cells 30 minutes after transfection and left overnight. The following day, transfection media was aspirated and fresh DMEM 10% FBS media was added to cells. 48 hours after infection transfection, U2OS cells were harvested and lysed by a single freeze thaw cycle. Serially diluted lysates were plated onto a confluent monolayer of U2OS cells and eGFP positive (CopMD5p targeted) or mCherry positive (CopMd3p targeted) plaques were isolated and purified through 5 rounds of plaque purifications.

Double major deleted vaccinia viruses were generated by co-infection of CopMD5p and CopMd3p deleted vaccinia viruses at an MOI of 5 for each virus in U2OS cells. Cells were harvested the next day and lysed by one round of freeze thaw. Lysates were serially diluted and plated onto a confluent monolayer of U2OS cells and selected for double positive plaques (eGFP+mCherry). Plaques were purified by 5 rounds of plaque purification.

An exemplary scheme for the production of modified orthopoxvirus vectors (e.g., modified vaccinia viral vectors, such as modified Copenhagen vaccinia viral vectors) of the disclosure is shown in FIG. 25.

Example 19—SKV-GFP (CopMD5p3p-B8R−) has Similar Efficacy in Tumour Control Compared to SKV (CopMD5p3p-B8R+)

The vaccinia virus (VV) B8R gene encodes a secreted protein with homology to gamma interferon receptor (IFN-γ). In vitro, the B8R protein binds to and neutralizes the antiviral activity of several species of gamma inteterferon including human and rat gamma interferon; it does not, however, bind significantly to murine IFN-γ. Here we describe the construction and characterization of recombinant VVs lacking the B8R gene. Homologous recombination between the targeting construct and the B8R locus resulted in the replacement of 75% of the B8R gene with the eGFP transgenes flanked by two loxP sites (SKV-GFP).

B8R-viruses showed similar efficacy to B8R+ viruses. FIG. 38. Survival of mice treated with either SKV or SKV-GFP was assessed. 5×10⁶ CT26-LacZ cells were seeded subcutaneously on day 0. On day 14, 16 and 18 tumours were treated at a dose of 107 pfu with an intratumoural injection of either SKV or SKV-GFP. No significant decrease in efficacy was seen when the viruses injected had a deletion of the B8R locus.

Example 20—Infection of Normal Versus Cancer Cell Lines of SKV (CopMD5p3p-B8R+) Virus

Primary health cell viability was compared to that of cancer cells. Confluent normal or cancer cells were infected at a range of MOI (pfu/cell) for 48 hrs, after which viability was quantified. As indicated in FIG. 36, SKV-B8R+ virus preferentially infects cancer cells.

Example 21—SKV (CopMD5p3p-B8R+) does not Impair Interferon Signaling

Interferon signaling was assessed by determining the number of genes in the interferon pathway that are upregulated (induced expression) or downregulated (repressed expression) in a variety of normal cell lines and one cancer cell line (786-0). FIG. 37 Confluent monolayers of 1 million cells were infected at an MOI of 3 (3×10⁶ PFU) for 18h with either SKV (CopMD5p3p-B8R+) or the parental Copenhagen virus strain having the TK gene disabled. RNA was sequenced using RNA-seq and gene expression of interferon genes was determined after read mapping a expression normalization. While the SKV (CopMD5p3p-B8R+) virus mostly induces genes in the interferon pathway the parental Copenhagen represses genes. This suggests SKV (CopMD5p3p-B8R+) is able to induce Type I Interferon signaling which is critical in viral clearance of normal cells.

Example 22—B8R Negative Vaccinia Virus Engineered to Express Flt3L, IL-12 TM and Anti-hCTLA-4

Modified vaccinia viruses containing both the CopMD5p3p and B8R deletions, as described above, were further engineered to express the immunotherapeutic transgenes. An SKV-123 virus (CopMD5p3p-B8R+-IL2TM-FLT3-antiCTLA4) expressing three transgenes was evaluated in terms of transgene expression kinetics. Confluent monolayers of 786-0 human adenocarcinoma cell lines were infected with SKV-123 virus at an MOI of 3 (3×10⁶ pfu). RNA was sequenced using RNA-seq and gene expression of inserted transgenes were determined after read mapping after expression normalization. Transgene expression peaked at 3-4 hours after cell infection. See FIG. 39.

Example 23 SKV Expressing Murine IL-12 p35 Membrane Bound (SKVm-3) has Greater Efficacy in Controlling Murine Tumors

The survival of mice treated with either SKV (CopMD5p3p-B8R+) or SKVm-3 (CopMD5p3p-B8R+-IL12TM) virus (expressing murine membrane bound p35 IL-12) was assessed. 5×10⁶ CT26-LacZ cells were seeded sub cutaneously on day 0. On day 14, 16 and 18 tumours were treated at a dose of 1e7 pfu with an intratumoural injection of either SKV or SKVm-3. Although SKV virus extends survival of mice bearing CT26 colon tuomurs. SKVm-3 expression of IL-12 is able to induce remissions that lead to durable cures. See FIG. 40.

Example 24—Major Double Deletions in Engineered in Various Vaccinia Strains Enhance Cancer Cell Killing In Vitro

Hela cells were infected at an MOI of 0.1 with the following strains of engineered vaccinia viruses: (1) parental wildtype virus (wt); (2) 5 prime major deleted (5p), (3) 3 prime major deleted (3p), and (4) recombined 5 prime and 3 prime major double deleted (5p3p). Cell viability was quantified by alamar blue assay 72 hours post infection. Both 5p and 5p3p major double deleted vaccinia strains are more cytotoxic in HeLa cells when compared to their parental wildtype and 3p major deleted strains. See FIG. 41. FIG. 42 depicts a summary of the major deleted Vaccinia strains, and the effect of 5p, 3p and 5p3p deletions on syncytia, cytotoxicity and replication. CD-1 nude mice were treated with 1×10⁷ pfu via intravenously tail vein injection and measured at the indicated timepoints. 5p3p vaccinia strains did not induce weight loss compared to wildtype strains. FIG. 43. Mice were also examined for pox lesions 6 days post-injection. 5p3p vaccinia strains do not induce pox lesions compared to wildtype strains. FIG. 44.

Some Embodiments

All publications, patents, and patent applications mentioned in this specification are incorporated herein by reference to the same extent as if each independent publication or patent application was specifically and individually indicated to be incorporated by reference.

While the invention has been described in connection with specific embodiments thereof, it will be understood that it is capable of further modifications and this application is intended to cover any variations, uses, or adaptations of the invention following, in general, the principles of the invention and including such departures from the invention that come within known or customary practice within the art to which the invention pertains and may be applied to the essential features hereinbefore set forth, and follows in the scope of the claims.

Some embodiments are within the claims. 

What is claimed:
 1. A nucleic acid comprising a recombinant orthoorthopoxvirus genome, wherein said recombinant orthoorthopoxvirus genome comprises a deletion of at least 2, 3, 4, 5, 6, 7, 8, 9, 10, 11, 12, 13, 14, 15, 16, 17, 18, 19, 20, 21, 22, or 23 genes, each independently selected from the group consisting of: C2L, C1L, N1L, N2L, M1L, M2L, K1L, K2L, K3L, K4L, K5L, K6L, K7R, F1L, F2L, F3L, B14R, B15R, B16R, B17L, B18R, B19R, B20R.
 2. The nucleic acid of claim 1, wherein said deletion comprises a deletion of each of said: C2L, C1 L, N1L, N2L, M1L, M2L, K1L, K2L, K3L, K4L, K5L, K6L, K7R, F1L, F2L, F3L, B14R, B15R, B16R, B17L, B18R, B19R, B20R genes.
 3. A nucleic acid comprising a recombinant orthopoxvirus genome, wherein said recombinant orthopoxvirus genome comprises a deletion of at least 1, 2, 3, 4, 5, 6, or 7 genes selected from the group consisting of B14R, B15R, B16R, B17L, B18R, B19R, and B20R.
 4. The nucleic acid of claim 3, wherein said deletion comprises each of said B14R, B15R, B16R, B17L, B18R, B19R, and B20R genes.
 5. A nucleic acid comprising a recombinant orthopoxvirus genome, wherein said recombinant orthopoxvirus genome comprises a deletion of at least 1, 2, 3, 4, 5, 6, 7, 8, 9, 10, 11, 12, 13, 14, 15, or 16 genes selected from the group consisting of C2L, C1L, N1L, N2L, M1L, M2L, K1L, K2L, K3 L, K4L, K5L, K6L, K7R, F1L, F2L, and F3L.
 6. The nucleic acid of claim 5, wherein said deletion comprises each of said C2L, C1L, N1L, N2L, M1L, M2L, K1L, K2L, K3L, K4L, K5L, K6L, K7R, F1L, F2L, and F3L genes.
 7. A nucleic acid comprising a recombinant orthopoxvirus genome, wherein said recombinant orthopoxvirus genome comprises a deletion of at least 1 gene that encodes a caspase-9 inhibitor.
 8. The nucleic acid of any one of claims 1-6, wherein said recombinant orthopoxvirus genome comprises a deletion of at least 1 gene that encodes a caspase-9 inhibitor.
 9. The nucleic acid of claim 7 or 8, wherein said gene that encodes a caspase-9 inhibitor is F1L.
 10. A nucleic acid comprising a recombinant orthopoxvirus genome, wherein said recombinant orthopoxvirus genome comprises a deletion of at least 1 gene that encodes a BCL-2 inhibitor.
 11. The nucleic acid of any one of claims 1-9, wherein said recombinant orthopoxvirus genome comprises a deletion of at least 1 gene that encodes a BCL-2 inhibitor.
 12. The nucleic acid of claim 10 or 11, wherein said gene that encodes a BCL-2 inhibitor is N1L.
 13. A nucleic acid comprising a recombinant orthopoxvirus genome, wherein said recombinant orthopoxvirus genome comprises a deletion of at least 1 gene that encodes a dUTPase.
 14. The nucleic acid of any one of claims 1-12, wherein said recombinant orthopoxvirus genome comprises a deletion of at least 1 gene that encodes a dUTPase.
 15. The nucleic acid of claim 13 or 14, wherein said gene that encodes a dUTPase is F2L.
 16. A nucleic acid comprising a recombinant orthopoxvirus genome, wherein said recombinant orthopoxvirus genome comprises a deletion of at least 1 gene that encodes a IFN-alpha/beta-receptor-like secreted glycoprotein.
 17. The nucleic acid of any one of claims 1-15, wherein said recombinant orthopoxvirus genome comprises a deletion of at least 1 gene that encodes a IFN-alpha/beta-receptor-like secreted glycoprotein.
 18. The nucleic acid of claim 16 or 17, wherein said gene that encodes a IFN-alpha/beta-receptor-like secreted glycoprotein is B19R.
 19. A nucleic acid comprising a recombinant orthopoxvirus genome, wherein said recombinant orthopoxvirus genome comprises a deletion of at least 1 gene that encodes an IL-1-beta-inhibitor.
 20. The nucleic acid of any one of claims 1-18, wherein said recombinant orthopoxvirus genome comprises a deletion of at least 1 gene that encodes an IL-1-beta-inhibitor.
 21. The nucleic acid of claim 19 or 20, wherein said gene that encodes an IL-1-beta-inhibitor is B16R.
 22. A nucleic acid comprising a recombinant orthopoxvirus genome, wherein said recombinant orthopoxvirus genome comprises a deletion of at least 1 gene that encodes a phospholipase-D.
 23. The nucleic acid of any one of claims 1-56, wherein said recombinant orthopoxvirus genome comprises a deletion of at least 1 gene that encodes a phospholipase-D.
 24. The nucleic acid of claim 22 or 23, wherein said gene that encodes a phospholipase-D is K4L.
 25. A nucleic acid comprising a recombinant orthopoxvirus genome, wherein said recombinant orthopoxvirus genome comprises a deletion of at least 1 gene that encodes a PKR inhibitor.
 26. The nucleic acid of any one of claims 1-24, wherein said recombinant orthopoxvirus genome comprises a deletion of at least 1 gene that encodes a PKR inhibitor.
 27. The nucleic acid of claim 25 or 26, wherein said gene that encodes a PKR inhibitor is K3L.
 28. A nucleic acid comprising a recombinant orthopoxvirus genome, wherein said recombinant orthopoxvirus genome comprises a deletion of at least 1 gene that encodes a serine protease inhibitor.
 29. The nucleic acid of any one of claims 1-27, wherein said recombinant orthopoxvirus genome comprises a deletion of at least 1 gene that encodes a serine protease inhibitor.
 30. The nucleic acid of claim 28 or 29, wherein said gene that encodes a serine protease inhibitor is K2L.
 31. A nucleic acid comprising a recombinant orthopoxvirus genome, wherein said recombinant orthopoxvirus genome comprises a deletion of at least 1 gene that encodes a TLR signaling inhibitor.
 32. The nucleic acid of any one of claims 1-30, wherein said recombinant orthopoxvirus genome comprises a deletion of at least 1 gene that encodes a TLR signaling inhibitor.
 33. The nucleic acid of claim 31 or 32, wherein said gene that encodes a TLR signaling inhibitor is N2L.
 34. A nucleic acid comprising a recombinant orthopoxvirus genome, wherein said recombinant orthopoxvirus genome comprises a deletion of at least 1 or 2 genes that encodes a kelch-like protein.
 35. The nucleic acid of any one of claims 1-33, wherein said recombinant orthopoxvirus genome comprises a deletion of at least 1 or 2 genes that encodes a kelch-like protein.
 36. The nucleic acid of any one of claims 34 or 35, wherein said genes that encode a kelch-like protein are, independently, selected from the group consisting of F3L and C2L.
 37. A nucleic acid comprising a recombinant orthopoxvirus genome, wherein said recombinant orthopoxvirus genome comprises a deletion of at least 1 or 2 genes that encodes a monoglyceride lipase.
 38. The nucleic acid of any one of claims 1-36, wherein said recombinant orthopoxvirus genome comprises a deletion of at least 1 gene that encodes a monoglyceride lipase.
 39. The nucleic acid of anyone of claims 37 or 38, wherein said genes that encode a monoglyceride lipase are, independently, selected from the group consisting of K5L and K6L.
 40. A nucleic acid comprising a recombinant orthopoxvirus genome, wherein said recombinant orthopoxvirus genome comprises a deletion of at least 1, 2 or 3 genes that encodes an NF-κB inhibitor.
 41. The nucleic acid of any one of claims 1-39, wherein said recombinant orthopoxvirus genome comprises a deletion of at least 1, 2 or 3 genes that encodes an NF-κB inhibitor.
 42. The nucleic acid of any one of claims 40 or 41, wherein said genes that encode an NF-κB inhibitor are, independently, selected from the group consisting of K7R, K1L, and M2L.
 43. A nucleic acid comprising a recombinant orthopoxvirus genome, wherein said recombinant orthopoxvirus genome comprises a deletion of at least 1, 2 or 3 genes that encodes an Ankyrin repeat protein.
 44. The nucleic acid of any one of claims 1-42, wherein said recombinant orthopoxvirus genome comprises a deletion of at least 1, 2 or 3 genes that encodes an Ankyrin repeat protein.
 45. The nucleic acid of any one of claims 43 or 44, wherein said genes that encode an Ankyrin repeat protein are, independently, selected from the group consisting of B18R, B20R, and M1L.
 46. A nucleic acid comprising a recombinant orthopoxvirus genome, wherein said recombinant orthopoxvirus genome comprises a deletion of at least 1 or 2 genes selected from the group consisting of B15R, B7L, and B14R.
 47. The nucleic acid of any one of claims 1-45, wherein said recombinant orthopoxvirus genome comprises a deletion of at least 1 or 2 genes selected from the group consisting of B15R, B17L, and B14R.
 48. The nucleic acid of claim 47, wherein said deletion comprises each of said B15R, B7L, and B14R genes.
 49. The nucleic acid of any one of claims 1-48, wherein said recombinant orthopoxvirus genome comprises a deletion of at least 1, 2, 3, 4, 5, 6, 7, 8, or 9 genes selected from the group of ITR genes consisting of B21R, B22R, B23R, B24R, B25R, B26R, B27R, B28R, and B29R.
 50. The nucleic acid of claim 49, wherein said deletion comprises each of said B21R, B22R, B23R, B24R, B25R, B26R, B27R, B28R, and B29R genes.
 51. The nucleic acid of any one of claims 1-50, wherein said vaccinia virus is a strain selected from the group consisting of Copenhagen, Western Reserve, Wyeth, Lister, EM63, ACAM2000, CV-1, modified vaccinia Ankara (MVA), Dairen I, GLV-1h68, IHD-J, L-IVP, LC16m8, LC16mO, Tashkent, Tian Tan, and WAU86/88-1.
 52. The nucleic acid of claim 51, wherein said vaccinia virus is a strain selected from the group consisting of Copenhagen, Western Reserve, Tian Tan, Wyeth, and Lister.
 53. The nucleic acid of claim 52, wherein said vaccinia virus is a Copenhagen strain vaccinia virus.
 54. The nucleic acid of any one of claims 1-53, wherein each of said deletions is a deletion of the entire polynucleotide encoding the corresponding gene.
 55. The nucleic acid of any one of claims 1-53, wherein each of said deletions is a deletion of a portion of the polynucleotide encoding the corresponding gene, and wherein said deletion is sufficient to render said gene nonfunctional upon introduction into a host cell.
 56. The nucleic acid of any one of claims 1-53, wherein said nucleic acid further comprises a transgene encoding a tumor-associated antigen.
 57. The nucleic acid of claim 56, wherein said tumor-associated antigen is a tumor-associated antigen listed in any one of Tables 3-30.
 58. The nucleic acid of claim 56, wherein said tumor-associated antigen is a tumor-associated antigen selected from the group consisting of CD19, CD33, EpCAM, CEA, PSMA, EGFRvIII, CD133, EGFR, CDH19, ENPP3, DLL3, MSLN, ROR1, HER2, HLAA2, EpHA2, EpHA3, MCSP, CSPG4, NG2, RON, FLT3, BCMA, CD20, FAPα, FRα, CA-9, PDGFRα, PDGFRβ, FSP1, S100A4, ADAM12m, RET, MET, FGFR, INSR, and NTRK.
 59. The nucleic acid of claim 56, wherein said tumor-associated antigen comprises MAGE-A3, or one or more fragments thereof.
 60. The nucleic acid of claim 56, wherein said tumor-associated antigen comprises one or more human papillomavirus (HPV) proteins, or fragments thereof.
 61. The nucleic acid of claim 60, wherein said tumor-associated antigen comprises (i) E6 and E7 proteins, or fragments thereof, of HPV16 and (ii) E6 and E7 proteins, or fragments thereof, of HPV18.
 62. The nucleic acid of claim 56, wherein said tumor-associated antigen comprises brachyury or one or more fragments thereof.
 63. The nucleic acid of claim 62, wherein said tumor-associated antigen comprises prostatic acid phosphatase, or one or more fragments thereof.
 64. The nucleic acid of any one of claims 1-63, wherein said nucleic acid further comprises a transgene encoding an immune checkpoint inhibitor.
 65. The nucleic acid of claim 64, wherein said immune checkpoint inhibitor is selected from the group consisting of OX40 ligand, ICOS ligand, anti-CD47 antibody or antigen-binding fragment thereof, anti-CD40/CD40L antibody or antigen-binding fragment thereof, anti-Lag3 antibody or antigen-binding fragment thereof, anti-CTLA-4 antibody or antigen-binding fragment thereof, anti-PD-L1 antibody or antigen-binding fragment thereof, anti-PD1 antibody or antigen-binding fragment thereof, and anti-Tim-3 antibody or antigen-binding fragment thereof.
 66. The nucleic acid of claim 64, wherein said immune checkpoint inhibitor is an anti-PD-L1 antibody or antigen-binding fragment thereof or an anti-CTLA-4 antibody or antigen-binding fragment thereof.
 67. The nucleic acid of claim 64, wherein said immune checkpoint inhibitor is an anti-PD1 antibody or antigen-binding fragment thereof.
 68. The nucleic acid of claim 64, wherein said immune checkpoint inhibitor is an anti-CTLA-4 antibody or antigen-binding fragment thereof.
 69. The nucleic acid of any one of claims 1-68, wherein said nucleic acid further comprises a transgene encoding an interleukin (IL).
 70. The nucleic acid of claim 69, wherein said interleukin is selected from the group consisting of IL-1 alpha, IL-1 beta, IL-2, IL-4, IL-7, IL-10, IL-12 p35, IL-12 p40, IL-12 p70, IL-15, IL-18, IL-21, and IL-23.
 71. The nucleic acid of claim 70, wherein said interleukin is selected from the group consisting of IL-12 p35, IL-12 p40, and IL-12 p70.
 72. The nucleic acid of claim 71, wherein said interleukin is membrane-bound.
 73. The nucleic acid of any one of claims 1-72, wherein said nucleic acid further comprises a transgene encoding an interferon (IFN).
 74. The nucleic acid of claim 73, wherein said interferon is selected from the group consisting of IFN-alpha, IFN-beta, IFN-delta, IFN-epsilon, IFN-tau, IFN-omega, IFN-zeta, and IFN-gamma.
 75. The nucleic acid of any one of claims 1-74, wherein said nucleic acid further comprises a transgene encoding a TNF superfamily member protein.
 76. The nucleic acid of claim 75, wherein said TNF superfamily member protein is selected from the group consisting of TRAIL, Fas ligand, LIGHT (TNFSF-14), TNF-alpha, and 4-1BB ligand.
 77. The nucleic acid of any one of claims 1-76 wherein said nucleic acid further comprises a transgene encoding a cytokine.
 78. The nucleic acid of claim 77, wherein said cytokine is selected from the group consisting of GM-CSF, Flt3 ligand, CD40 ligand, anti-TGF-beta, anti-VEGF-R2, and cGAS (guanyl adenylate cyclase).
 79. The nucleic acid of claim 78, wherein said cytokine is Flt3 ligand.
 80. A recombinant orthopoxvirus vector comprising a deletion of at least 2, 3, 4, 5, 6, 7, 8, 9, 10, 11, 12, 13, 14, 15, 16, 17, 18, 19, 20, 21, 22, or 23 genes, each independently selected from the group consisting of: C2L, C1L, N1L, N2L, M1L, M2L, K1L, K2L, K3L, K4L, K5L, K6L, K7R, F1L, F2L, F3L, B14R, B15R, B16R, B17L, B18R, B19R, B20R.
 81. A recombinant orthopoxvirus vector comprising a deletion of at least 1, 2, 3, 4, 5, 6 or 7 genes selected from the group consisting of B14R, B15R, B16R, B17L, B18R, B19R, and B20R.
 82. The recombinant orthopoxvirus vector of claim 80 or 81, wherein said vector comprises a deletion of at least 1, 2, 3, 4, 5, 6 or 7 genes selected from the group consisting of B14R, B15R, B16R, B17L, B18R, B19R, and B20R.
 83. A recombinant orthopoxvirus vector comprising a deletion of at least 1, 2, 3, 4, 5, 6, 7, 8, 9, 10, 11, 12, 13, 14, 15 or 16 genes selected from the group consisting of C2L, C1L, N1L, N2L, M1L, M2L, K1L, K2L, K3L, K4L, K5L, K6L, K7R, F1L, F2L, and F3L.
 84. The recombinant orthopoxvirus vector of any one of claim 80-82, wherein said vector comprises a deletion of at least 1, 2, 3, 4, 5, 6, 7, 8, 9, 10, 11, 12, 13, 14, 15 or 16 genes selected from the group consisting of C2L, C1L, N1L, N2L, M1L, M2L, K1L, K2L, K3L, K4L, K5L, K6L, K7R, F1L, F2L, and F3L.
 85. A recombinant orthopoxvirus vector comprising a deletion of at least 1 gene that encodes a caspase-9 inhibitor.
 86. The recombinant orthopoxvirus vector of any one of claims 80-84, wherein said vector comprises a deletion of at least 1 gene that encodes a caspase-9 inhibitor.
 87. The vector of claim 85 or 86, wherein said gene that encodes a caspase-9 inhibitor is F1L.
 88. A recombinant orthopoxvirus vector, wherein said vector comprises a deletion of at least 1 gene that encodes a BCL-2 inhibitor.
 89. The recombinant orthopoxvirus vector of any one of claims 80-87, wherein said vector comprises a deletion of at least 1 gene that encodes a BCL-2 inhibitor.
 90. The vector of claim 88 or 89, wherein said gene that encodes a BCL-2 inhibitor is N1L.
 91. A recombinant orthopoxvirus vector, wherein said vector comprises a deletion of at least 1 gene that encodes a dUTPase.
 92. The recombinant orthopoxvirus vector of any one of claims 80-90, wherein said vector comprises a deletion of at least 1 gene that encodes a dUTPase.
 93. The vector of claim 91 or 92, wherein said gene that encodes a dUTPase is F2L.
 94. A recombinant orthopoxvirus vector, wherein said vector comprises a deletion of at least 1 gene that encodes a IFN-alpha/beta-receptor-like secreted glycoprotein.
 95. The recombinant orthopoxvirus vector of any one of claims 80-93, wherein said vector comprises a deletion of at least 1 gene that encodes a IFN-alpha/beta-receptor-like secreted glycoprotein.
 96. The vector of claim 94 or 95, wherein said gene that encodes a IFN-alpha/beta-receptor-like secreted glycoprotein is B19R.
 97. A recombinant orthopoxvirus vector, wherein said vector comprises a deletion of at least 1 gene that encodes an IL-1-beta-inhibitor.
 98. The recombinant orthopoxvirus vector of any one of claims 80-96, wherein said vector comprises a deletion of at least 1 gene that encodes an IL-1-beta-inhibitor.
 99. The vector of claim 97 or 98, wherein said gene that encodes an IL-1-beta-inhibitor is B16R.
 100. A recombinant orthopoxvirus vector, wherein said vector comprises a deletion of at least 1 gene that encodes a phospholipase-D.
 101. The recombinant orthopoxvirus vector of any one of claims 80-99, wherein said vector comprises a deletion of at least 1 gene that encodes a phospholipase-D.
 102. The vector of claim 100 or 101, wherein said gene that encodes a phospholipase-D is K4L.
 103. A recombinant orthopoxvirus vector, wherein said vector comprises a deletion of at least 1 gene that encodes a PKR inhibitor.
 104. The recombinant orthopoxvirus vector of any one of claims 80-102, wherein said vector comprises a deletion of at least 1 gene that encodes a PKR inhibitor.
 105. The vector of claim 103 or 104, wherein said gene that encodes a PKR inhibitor is K3L.
 106. A recombinant orthopoxvirus vector, wherein said vector comprises a deletion of at least 1 gene that encodes a serine protease inhibitor.
 107. The recombinant orthopoxvirus vector of any one of claims 80-105, wherein said vector comprises a deletion of at least 1 gene that encodes a serine protease inhibitor.
 108. The vector of claim 106 or 107, wherein said gene that encodes a serine protease inhibitor is K2L.
 109. A recombinant orthopoxvirus vector, wherein said vector comprises a deletion of at least 1 gene that encodes a TLR signaling inhibitor.
 110. The recombinant orthopoxvirus vector of any one of claims 80-108, wherein said vector comprises a deletion of at least 1 gene that encodes a TLR signaling inhibitor.
 111. The vector of claim 109 or 110, wherein said gene that encodes a TLR signaling inhibitor is N2L.
 112. A recombinant orthopoxvirus vector, wherein said vector comprises a deletion of at least 1 or 2 genes that encodes a kelch-like protein.
 113. The recombinant orthopoxvirus vector of any one of claims 80-111, wherein said vector comprises a deletion of at least 1 or 2 genes that encodes a kelch-like protein.
 114. The vector of any one of claims 112-113, wherein said genes that encode a kelch-like protein are, independently, selected from the group consisting of F3L and C2L.
 115. A recombinant orthopoxvirus vector, wherein said vector comprises a deletion of at least 1 or 2 genes that encodes a monoglyceride lipase.
 116. The recombinant orthopoxvirus vector of any one of claims 80-114, wherein said vector comprises a deletion of at least 1 or 2 genes that encodes a monoglyceride lipase.
 117. The vector of anyone of claims 115-116, wherein said genes that encode a monoglyceride lipase are, independently, selected from the group consisting of K5L and K6L.
 118. A recombinant orthopoxvirus vector, wherein said vector comprises a deletion of at least 1, 2 or 3 genes that encodes an NF-κB inhibitor.
 119. The recombinant orthopoxvirus vector of any one of claims 80-117, wherein said vector comprises a deletion of at least 1, 2 or 3 genes that encodes an NF-κB inhibitor.
 120. The vector of any one of claims 118-119, wherein said genes that encode an NF-κB inhibitor are, independently, selected from the group consisting of K7R, K1L, and M2L.
 121. A recombinant orthopoxvirus vector, wherein said vector comprises a deletion of at least 1, 2 or 3 genes that encodes an Ankyrin repeat protein.
 122. The recombinant orthopoxvirus vector of any one of claims 80-120, wherein said vector comprises a deletion of at least 1, 2 or 3 genes that encodes an Ankyrin repeat protein.
 123. The recombinant orthopoxvirus vector of any one of claims 121-122, wherein said genes that encode an Ankyrin repeat protein are, independently, selected from the group consisting of B18R, B20R, and M1L.
 124. A recombinant orthopoxvirus vector, wherein said vector comprises a deletion of at least 1 or 2 genes selected from the group consisting of B15R, B17L, and B14R.
 125. The recombinant orthopoxvirus vector of any one of claims 80-123, wherein said vector comprises a deletion of at least 1 or 2 genes selected from the group consisting of B15R, B17L, and B14R.
 126. The vector of claim 124 or 125, wherein said deletion comprises each of said B15R, B17L, and B14R genes.
 127. The recombinant orthopoxvirus vector of any one of claims 80-126, wherein said vector comprises a deletion of at least 1, 2, 3, 4, 5, 6, 7, 8 or 9 genes selected from the group of ITR genes consisting of B21R, B22R, B23R, B24R, B25R, B26R, B27R, B28R, and B29R.
 128. The recombinant orthopoxvirus vector of any one of claims 80-127, wherein said vaccinia virus is a strain selected from the group consisting of Copenhagen, Western Reserve, Wyeth, Lister, EM63, ACAM2000, CV-1, modified vaccinia Ankara (MVA), Dairen I, GLV-1h68, IHD-J, L-IVP, LC16m8, LC16mO, Tashkent, Tian Tan, and WAU86/88-1.
 129. The recombinant orthopoxvirus vector of claim 128, wherein said vaccinia virus is a strain selected from the group consisting of Copenhagen, Western Reserve, Tian Tan, Wyeth, and Lister.
 130. The recombinant orthopoxvirus vector of claim 129, wherein said vaccinia virus is a Copenhagen strain vaccinia virus.
 131. The recombinant orthopoxvirus vector of any one of claim 129, wherein said deletions is a deletion of the entire polynucleotide encoding the corresponding gene.
 132. The recombinant orthopoxvirus vector of any one of claims 80-131, wherein each of said deletions is a deletion of a portion of the polynucleotide encoding the corresponding gene, and wherein said deletion is sufficient to render said gene nonfunctional upon introduction into a host cell.
 133. The recombinant orthopoxvirus vector of any one of claims 80-132, wherein said vector further comprises a transgene encoding a tumor-associated antigen.
 134. The recombinant orthopoxvirus vector of any one of claims 80-133, wherein said recombinant orthopoxvirus vector further comprises a transgene encoding a tumor-associated antigen.
 135. The recombinant orthopoxvirus vector of claim 134, wherein said tumor-associated antigen is a tumor-associated antigen listed in any one of Tables 3-30.
 136. The recombinant orthopoxvirus vector of claim 134, wherein said tumor-associated antigen is a tumor-associated antigen selected from the group consisting of CD19, CD33, EpCAM, CEA, PSMA, EGFRvIII, CD274, EGFR, CDH19, ENPP3, DLL3, MSLN, ROR1, HER2, HLAA2, EpHA2, EpHA3, MCSP, CSPG4, NG2, RON, FLT3, BCMA, CD20, FAPα, FRα, CA-9, PDGFRα, PDGFRβ, FSP1, S100A4, ADAM12m, RET, MET, FGFR, INSR, and NTRK.
 137. The recombinant orthopoxvirus vector of claim 134, wherein said tumor-associated antigen comprises MAGE-A3, or one or more fragments thereof.
 138. The recombinant orthopoxvirus vector of claim 134, wherein said tumor-associated antigen comprises one or more human papillomavirus (HPV) proteins, or fragments thereof.
 139. The recombinant orthopoxvirus vector of claim 134, wherein said tumor-associated antigen comprises (i) E6 and E7 proteins, or fragments thereof, of HPV16 and (ii) E6 and E7 proteins, or fragments thereof, of HPV18.
 140. The recombinant orthopoxvirus vector of claim 134, wherein said tumor-associated antigen comprises brachyury or one or more fragments thereof.
 141. The recombinant orthopoxvirus vector of claim 134, wherein said tumor-associated antigen comprises prostatic acid phosphatase, or one or more fragments thereof.
 142. The recombinant orthopoxvirus vector of any one of claims 80-141, wherein said recombinant orthopoxvirus vector further comprises a transgene encoding an immune checkpoint inhibitor.
 143. The recombinant orthopoxvirus vector of claim 142, wherein said immune checkpoint inhibitor is selected from the group consisting of OX40 ligand, ICOS ligand, anti-CD47 antibody or antigen-binding fragment thereof, anti-CD40/CD40L antibody or antigen-binding fragment thereof, anti-Lag3 antibody or antigen-binding fragment thereof, anti-CTLA-4 antibody or antigen-binding fragment thereof, anti-PD-L1 antibody or antigen-binding fragment thereof, anti-PD1 antibody or antigen-binding fragment thereof, and anti-Tim-3 antibody or antigen-binding fragment thereof.
 144. The recombinant orthopoxvirus vector of claim 143, wherein said immune checkpoint inhibitor is an anti-PD-L1 antibody or antigen-binding fragment thereof or an anti-CTLA-4 antibody or antigen-binding fragment thereof.
 145. The recombinant orthopoxvirus vector of claim 143, wherein said immune checkpoint inhibitor is an anti-PD1 antibody or antigen-binding fragment thereof.
 146. The recombinant orthopoxvirus vector of claim 143, wherein said immune checkpoint inhibitor is an anti-CTLA-4 antibody or antigen-binding fragment thereof.
 147. The recombinant orthopoxvirus vector of any one of claims 80-146, wherein said recombinant orthopoxvirus vector further comprises a transgene encoding an interleukin (IL).
 148. The recombinant orthopoxvirus vector of claim 147, wherein said interleukin is selected from the group consisting of IL-1 alpha, IL-1 beta, IL-2, IL-4, IL-7, IL-10, IL-12 p35, IL-12 p40, IL-12 p70, IL-15, IL-18, IL-21, and IL-23.
 149. The recombinant orthopoxvirus vector of claim 147, wherein said interleukin is selected from the group consisting of IL-12 p35, IL-12 p40, and IL-12 p70.
 150. The recombinant orthopoxvirus vector of claim 147, wherein said interleukin is membrane-bound.
 151. The recombinant orthopoxvirus vector of any one of claims 80-150, wherein said recombinant orthopoxvirus vector further comprises a transgene encoding an interferon (IFN).
 152. The recombinant orthopoxvirus vector of claim 151, wherein said interferon is selected from the group consisting of IFN-alpha, IFN-beta, IFN-delta, IFN-epsilon, IFN-tau, IFN-omega, IFN-zeta, and IFN-gamma.
 153. The recombinant orthopoxvirus vector of any one of claims 80-152, wherein said recombinant orthopoxvirus vector further comprises a transgene encoding a TNF superfamily member protein.
 154. The recombinant orthopoxvirus vector of claim 153, wherein said TNF superfamily member protein is selected from the group consisting of TRAIL, Fas ligand, LIGHT (TNFSF-14), TNF-alpha, and 4-1BB ligand.
 155. The recombinant orthopoxvirus vector of any one of claims 80-154 wherein said recombinant orthopoxvirus vector further comprises a transgene encoding a cytokine.
 156. The recombinant orthopoxvirus vector of claim 155, wherein said cytokine is selected from the group consisting of GM-CSF, Flt3 ligand, CD40 ligand, anti-TGF-beta, anti-VEGF-R2, and cGAS (guanyl adenylate cyclase).
 157. The recombinant orthopoxvirus vector of claim 156, wherein said cytokine is Flt3 ligand.
 158. The nucleic acid of any one of claims 1-79, or the recombinant orthopoxvirus vector of any one of claims 80-157, wherein said nucleic acid or said recombinant orthopoxvirus vector comprises the Thymidine Kinase (TK) gene.
 159. The nucleic acid of any one of claims 1-79, or the recombinant orthopoxvirus vector of any one of claims 80-157, wherein said nucleic acid or said recombinant orthopoxvirus vector comprises the ribonucleotide reductase gene.
 160. The nucleic acid of any one of claims 1-79, or the recombinant orthopoxvirus vector of any one of claims 80-157, wherein upon contacting a population of mammalian cells with said nucleic acid or said recombinant orthopoxvirus vector, the cells exhibit increased syncytia formation relative to a population of mammalian cells of the same type contacted with a form of the orthopoxvirus vector that does not comprise said deletions.
 161. The nucleic acid of any one of claims 1-79, or the recombinant orthopoxvirus vector of any one of claims 80-157, wherein upon contacting a population of mammalian cells with said nucleic acid or said recombinant orthopoxvirus vector, the cells exhibit increased spreading of the orthopoxvirus vector relative to a population of mammalian cells of the same type contacted with a form of the orthopoxvirus vector that does not comprise said deletions.
 162. The nucleic acid of any one of claims 1-79, or the recombinant orthopoxvirus vector of any one of claims 80-157, wherein said nucleic acid or said recombinant orthopoxvirus vector exerts an increased cytotoxic effect on a population of mammalian cells relative to that of a form of the orthopoxvirus vector that does not comprise said deletions.
 163. The nucleic acid or the recombinant orthopoxvirus vector of claim 162, wherein said mammalian cells are human cells.
 164. The nucleic acid or the recombinant orthopoxvirus vector of claim 163, wherein said human cells are cancer cells.
 165. A packaging cell line comprising the nucleic acid of any one of claims 1-79, or the recombinant orthopoxvirus vector of any one of claims 80-157.
 166. A method of treating cancer in a mammalian patient, said method comprising administering a therapeutically effective amount of the nucleic acid of any one of claims 1-79, or the recombinant orthopoxvirus vector of any one of claims 80-157 to said patient.
 167. The method of claim 166, wherein said mammalian patient is a human patient.
 168. The method of claim 166 or 167, wherein said cancer is selected from the group consisting of leukemia, lymphoma, liver cancer, bone cancer, lung cancer, brain cancer, bladder cancer, gastrointestinal cancer, breast cancer, cardiac cancer, cervical cancer, uterine cancer, head and neck cancer, gallbladder cancer, laryngeal cancer, lip and oral cavity cancer, ocular cancer, melanoma, pancreatic cancer, prostate cancer, colorectal cancer, testicular cancer, and throat cancer.
 169. The method of claim 166 or 167, wherein said cancer is selected from the group consisting of acute lymphoblastic leukemia (ALL), acute myeloid leukemia (AML), chronic lymphocytic leukemia (CLL), chronic myelogenous leukemia (CML), adrenocortical carcinoma, AIDS-related lymphoma, primary CNS lymphoma, anal cancer, appendix cancer, astrocytoma, atypical teratoid/rhabdoid tumor, basal cell carcinoma, bile duct cancer, extrahepatic cancer, ewing sarcoma family, osteosarcoma and malignant fibrous histiocytoma, central nervous system embryonal tumors, central nervous system germ cell tumors, craniopharyngioma, ependymoma, bronchial tumors, burkitt lymphoma, carcinoid tumor, primary lymphoma, chordoma, chronic myeloproliferative neoplasms, colon cancer, extrahepatic bile duct cancer, ductal carcinoma in situ (DCIS), endometrial cancer, ependymoma, esophageal cancer, esthesioneuroblastoma, extracranial germ cell tumor, extragonadal germ cell tumor, fallopian tube cancer, fibrous histiocytoma of bone, gastrointestinal carcinoid tumor, gastrointestinal stromal tumors (GIST), testicular germ cell tumor, gestational trophoblastic disease, glioma, childhood brain stem glioma, hairy cell leukemia, hepatocellular cancer, langerhans cell histiocytosis, hodgkin lymphoma, hypopharyngeal cancer, islet cell tumors, pancreatic neuroendocrine tumors, wilms tumor and other childhood kidney tumors, langerhans cell histiocytosis, small cell lung cancer, cutaneous T cell lymphoma, intraocular melanoma, merkel cell carcinoma, mesothelioma, metastatic squamous neck cancer, midline tract carcinoma, multiple endocrine neoplasia syndromes, multiple myeloma/plasma cell neoplasm, myelodysplastic syndromes, nasal cavity and paranasal sinus cancer, nasopharyngeal cancer, neuroblastoma, non-hodgkin lymphoma (NHL), non-small cell lung cancer (NSCLC), epithelial ovarian cancer, germ cell ovarian cancer, low malignant potential ovarian cancer, pancreatic neuroendocrine tumors, papillomatosis, paraganglioma, paranasal sinus and nasal cavity cancer, parathyroid cancer, penile cancer, pharyngeal cancer, pheochromocytoma, pituitary tumor, pleuropulmonary blastoma, primary peritoneal cancer, rectal cancer, retinoblastoma, rhabdomyosarcoma, salivary gland cancer, kaposi sarcoma, rhabdomyosarcoma, sézary syndrome, small intestine cancer, soft tissue sarcoma, throat cancer, thymoma and thymic carcinoma, thyroid cancer, transitional cell cancer of the renal pelvis and ureter, urethral cancer, endometrial uterine cancer, uterine sarcoma, vaginal cancer, vulvar cancer, and Waldenström macroglobulinemia.
 170. The method of any one of claims 166-169, wherein said method further comprises administering to said patient an immune checkpoint inhibitor.
 171. The method of claim 170, wherein said immune checkpoint inhibitor is selected from the group consisting of OX40 ligand, COS ligand, anti-CD47 antibody or antigen-binding fragment thereof, anti-CD40/CD40L antibody or antigen-binding fragment thereof, anti-Lag3 antibody or antigen-binding fragment thereof, anti-CTLA-4 antibody or antigen-binding fragment thereof, anti-PD-L1 antibody or antigen-binding fragment thereof, anti-PD1 antibody or antigen-binding fragment thereof, and anti-Tim-3 antibody or antigen-binding fragment thereof.
 172. The method of claim 170, wherein said immune checkpoint inhibitor is an anti-PD1 antibody or antigen-binding fragment thereof or an anti-CTLA-4 antibody or antigen-binding fragment thereof.
 173. The method of claim 170, wherein said immune checkpoint inhibitor is an anti-PD1 antibody or antigen-binding fragment thereof.
 174. The method of claim 170, wherein said immune checkpoint inhibitor is an anti-CTLA-4 antibody or antigen-binding fragment thereof.
 175. The method of any one of claims 166-174, wherein said method further comprises administering to said patient an interleukin.
 176. The method of claim 175, wherein said interleukin is selected from the group consisting of IL-1 alpha, IL-1 beta, IL-2, IL-4, IL-7, IL-10, IL-12 p35, IL-12 p40, IL-12 p70, IL-15, IL-18, IL-21, and IL-23.
 177. The method of claim 175, wherein said interleukin is selected from the group consisting of IL-12 p35, IL-12 p40, and IL-12 p70.
 178. The method of any one of claims 175-177, wherein said interleukin is membrane-bound.
 179. The method of anyone of claims 166-178, wherein said method further comprises administering to said patient an interferon.
 180. The method of claim 179, wherein said interferon is selected from the group consisting of IFN-alpha, IFN-beta, IFN-delta, IFN-epsilon, IFN-tau, IFN-omega, IFN-zeta, and IFN-gamma.
 181. The method of any one of claims 165-180, wherein said method further comprises administering to said patient a TNF superfamily member protein.
 182. The method of claim 181, wherein said TNF superfamily member protein is selected from the group consisting of TRAIL, Fas ligand, LIGHT (TNFSF-14), TNF-alpha, and 4-1BB ligand.
 183. The method of any one of claims 166-182, wherein said method further comprises administering to said patient a cytokine.
 184. The method of claim 183, wherein said cytokine is selected from the group consisting of GM-CSF, Flt3 ligand, CD40 ligand, anti-TGF-beta, anti-VEGF-R2, and cGAS (guanyl adenylate cyclase).
 185. The method of claim 184, wherein said cytokine is Flt3 ligand.
 186. A kit comprising the nucleic acid of any one of claims 1-79 or the recombinant orthopoxvirus vector of any one of claims 80-157 and a package insert instructing a user of said kit to express said nucleic acid or said vector in a host cell.
 187. A kit comprising the nucleic acid of any one of claims 1-79 or the recombinant orthopoxvirus vector of any one of claims 80-157 and a package insert instructing a user to administer a therapeutically effective amount of said nucleic acid or recombinant orthopoxvirus vector to a mammalian patient having cancer, thereby treating said cancer.
 188. The kit of claim 187, wherein said mammalian patient is a human patient.
 189. The the nucleic acid of any one of claims 1-79 or the recombinant orthopoxvirus vector of any one of claims 80-157 wherein the B8R gene is deleted.
 190. The nucleic acid or the recombinant orthopox virus of claim 189, wherein at least one transgene is inserted into the locus of the deleted B8R gene.
 191. The nucleic acid or the recombinant orthopox virus of claim 190, wherein at least two transgenes are inserted into the locus of the deleted B8R gene.
 192. The nucleic acid or the recombinant orthopox virus of claim 191, wherein at least three transgenes are inserted into the locus of the deleted B8R gene.
 193. The nucleic acid or the recombinant orthopox virus of claims 189-192, wherein at least one additional transgene is inserted at locus that is not the locus of the B8R gene.
 194. The nucleic acid or the recombinant orthopox virus of claim 193, wherein the locus is the boundary of the 5p deletion.
 195. The nucleic acid or the recombinant orthopox virus of claim 193, wherein the locus is the boundary of the 3p deletion.
 196. The nucleic acid or the recombinant orthopox virus of claims 189-192, wherein at least one of the following transgenes is inserted: IL-12TM, FLT3-L or anti-CLTA-4 antibody. 